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1.
Annu Rev Biochem ; 93(1): 211-231, 2024 Aug.
Artículo en Inglés | MEDLINE | ID: mdl-38603556

RESUMEN

Almost all outer membrane proteins (OMPs) in Gram-negative bacteria contain a ß-barrel domain that spans the outer membrane (OM). To reach the OM, OMPs must be translocated across the inner membrane by the Sec machinery, transported across the crowded periplasmic space through the assistance of molecular chaperones, and finally assembled (folded and inserted into the OM) by the ß-barrel assembly machine. In this review, we discuss how considerable new insights into the contributions of these factors to OMP biogenesis have emerged in recent years through the development of novel experimental, computational, and predictive methods. In addition, we describe recent evidence that molecular machines that were thought to function independently might interact to form dynamic intermembrane supercomplexes. Finally, we discuss new results that suggest that OMPs are inserted primarily near the middle of the cell and packed into supramolecular structures (OMP islands) that are distributed throughout the OM.


Asunto(s)
Proteínas de la Membrana Bacteriana Externa , Chaperonas Moleculares , Proteínas de la Membrana Bacteriana Externa/metabolismo , Proteínas de la Membrana Bacteriana Externa/genética , Proteínas de la Membrana Bacteriana Externa/química , Chaperonas Moleculares/metabolismo , Chaperonas Moleculares/genética , Chaperonas Moleculares/química , Transporte de Proteínas , Pliegue de Proteína , Bacterias Gramnegativas/metabolismo , Bacterias Gramnegativas/genética , Membrana Externa Bacteriana/metabolismo , Modelos Moleculares , Proteínas de Escherichia coli/metabolismo , Proteínas de Escherichia coli/genética , Proteínas de Escherichia coli/química , Canales de Translocación SEC/metabolismo , Canales de Translocación SEC/genética , Canales de Translocación SEC/química , Periplasma/metabolismo
2.
Cell ; 186(5): 1039-1049.e17, 2023 03 02.
Artículo en Inglés | MEDLINE | ID: mdl-36764293

RESUMEN

Hsp60 chaperonins and their Hsp10 cofactors assist protein folding in all living cells, constituting the paradigmatic example of molecular chaperones. Despite extensive investigations of their structure and mechanism, crucial questions regarding how these chaperonins promote folding remain unsolved. Here, we report that the bacterial Hsp60 chaperonin GroEL forms a stable, functionally relevant complex with the chaperedoxin CnoX, a protein combining a chaperone and a redox function. Binding of GroES (Hsp10 cofactor) to GroEL induces CnoX release. Cryoelectron microscopy provided crucial structural information on the GroEL-CnoX complex, showing that CnoX binds GroEL outside the substrate-binding site via a highly conserved C-terminal α-helix. Furthermore, we identified complexes in which CnoX, bound to GroEL, forms mixed disulfides with GroEL substrates, indicating that CnoX likely functions as a redox quality-control plugin for GroEL. Proteins sharing structural features with CnoX exist in eukaryotes, suggesting that Hsp60 molecular plugins have been conserved through evolution.


Asunto(s)
Chaperonas Moleculares , Pliegue de Proteína , Microscopía por Crioelectrón , Chaperonas Moleculares/metabolismo , Oxidación-Reducción , Chaperoninas/química , Chaperoninas/metabolismo , Chaperonina 60/química , Chaperonina 10/metabolismo
3.
Annu Rev Biochem ; 91: 651-678, 2022 06 21.
Artículo en Inglés | MEDLINE | ID: mdl-35287476

RESUMEN

The endoplasmic reticulum (ER) is the site of membrane protein insertion, folding, and assembly in eukaryotes. Over the past few years, a combination of genetic and biochemical studies have implicated an abundant factor termed the ER membrane protein complex (EMC) in several aspects of membrane protein biogenesis. This large nine-protein complex is built around a deeply conserved core formed by the EMC3-EMC6 subcomplex. EMC3 belongs to the universally conserved Oxa1 superfamily of membrane protein transporters, whereas EMC6 is an ancient, widely conserved obligate partner. EMC has an established role in the insertion of transmembrane domains (TMDs) and less understood roles during the later steps of membrane protein folding and assembly. Several recent structures suggest hypotheses about the mechanism(s) of TMD insertion by EMC, with various biochemical and proteomics studies beginning to reveal the range of EMC's membrane protein substrates.


Asunto(s)
Retículo Endoplásmico , Proteínas de la Membrana , Retículo Endoplásmico/metabolismo , Proteínas de la Membrana/metabolismo , Biosíntesis de Proteínas , Dominios Proteicos , Pliegue de Proteína
4.
Annu Rev Biochem ; 91: 33-59, 2022 06 21.
Artículo en Inglés | MEDLINE | ID: mdl-35287472

RESUMEN

Single-molecule magnetic tweezers deliver magnetic force and torque to single target molecules, permitting the study of dynamic changes in biomolecular structures and their interactions. Because the magnetic tweezer setups can generate magnetic fields that vary slowly over tens of millimeters-far larger than the nanometer scale of the single molecule events being observed-this technique can maintain essentially constant force levels during biochemical experiments while generating a biologically meaningful force on the order of 1-100 pN. When using bead-tether constructs to pull on single molecules, smaller magnetic beads and shorter submicrometer tethers improve dynamic response times and measurement precision. In addition, employing high-speed cameras, stronger light sources, and a graphics programming unit permits true high-resolution single-molecule magnetic tweezers that can track nanometer changes in target molecules on a millisecond or even submillisecond time scale. The unique force-clamping capacity of the magnetic tweezer technique provides a way to conduct measurements under near-equilibrium conditions and directly map the energy landscapes underlying various molecular phenomena. High-resolution single-molecule magnetic tweezerscan thus be used to monitor crucial conformational changes in single-protein molecules, including those involved in mechanotransduction and protein folding.


Asunto(s)
ADN , Mecanotransducción Celular , ADN/química , Fenómenos Magnéticos
5.
Cell ; 185(1): 158-168.e11, 2022 01 06.
Artículo en Inglés | MEDLINE | ID: mdl-34995514

RESUMEN

Small molecule chaperones have been exploited as therapeutics for the hundreds of diseases caused by protein misfolding. The most successful examples are the CFTR correctors, which transformed cystic fibrosis therapy. These molecules revert folding defects of the ΔF508 mutant and are widely used to treat patients. To investigate the molecular mechanism of their action, we determined cryo-electron microscopy structures of CFTR in complex with the FDA-approved correctors lumacaftor or tezacaftor. Both drugs insert into a hydrophobic pocket in the first transmembrane domain (TMD1), linking together four helices that are thermodynamically unstable. Mutating residues at the binding site rendered ΔF508-CFTR insensitive to lumacaftor and tezacaftor, underscoring the functional significance of the structural discovery. These results support a mechanism in which the correctors stabilize TMD1 at an early stage of biogenesis, prevent its premature degradation, and thereby allosterically rescuing many disease-causing mutations.


Asunto(s)
Aminopiridinas/metabolismo , Benzodioxoles/metabolismo , Regulador de Conductancia de Transmembrana de Fibrosis Quística/metabolismo , Indoles/metabolismo , Pliegue de Proteína , Aminopiridinas/química , Aminopiridinas/uso terapéutico , Animales , Benzodioxoles/química , Benzodioxoles/uso terapéutico , Sitios de Unión , Células CHO , Membrana Celular/química , Membrana Celular/metabolismo , Cricetulus , Microscopía por Crioelectrón , Fibrosis Quística/tratamiento farmacológico , Fibrosis Quística/metabolismo , Regulador de Conductancia de Transmembrana de Fibrosis Quística/química , Regulador de Conductancia de Transmembrana de Fibrosis Quística/genética , Células HEK293 , Humanos , Interacciones Hidrofóbicas e Hidrofílicas , Indoles/química , Indoles/uso terapéutico , Chaperonas Moleculares/química , Chaperonas Moleculares/metabolismo , Chaperonas Moleculares/uso terapéutico , Mutación , Dominios Proteicos/genética , Células Sf9 , Transfección
6.
Cell ; 185(7): 1143-1156.e13, 2022 03 31.
Artículo en Inglés | MEDLINE | ID: mdl-35294859

RESUMEN

Transmembrane ß barrel proteins are folded into the outer membrane (OM) of Gram-negative bacteria by the ß barrel assembly machinery (BAM) via a poorly understood process that occurs without known external energy sources. Here, we used single-particle cryo-EM to visualize the folding dynamics of a model ß barrel protein (EspP) by BAM. We found that BAM binds the highly conserved "ß signal" motif of EspP to correctly orient ß strands in the OM during folding. We also found that the folding of EspP proceeds via "hybrid-barrel" intermediates in which membrane integrated ß sheets are attached to the essential BAM subunit, BamA. The structures show an unprecedented deflection of the membrane surrounding the EspP intermediates and suggest that ß sheets progressively fold toward BamA to form a ß barrel. Along with in vivo experiments that tracked ß barrel folding while the OM tension was modified, our results support a model in which BAM harnesses OM elasticity to accelerate ß barrel folding.


Asunto(s)
Proteínas de la Membrana Bacteriana Externa/ultraestructura , Pliegue de Proteína , Proteínas de la Membrana Bacteriana Externa/metabolismo , Microscopía por Crioelectrón , Escherichia coli/metabolismo , Proteínas de Escherichia coli/metabolismo
7.
Annu Rev Biochem ; 90: 349-373, 2021 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-33781075

RESUMEN

Codon-dependent translation underlies genetics and phylogenetic inferences, but its origins pose two challenges. Prevailing narratives cannot account for the fact that aminoacyl-tRNA synthetases (aaRSs), which translate the genetic code, must collectively enforce the rules used to assemble themselves. Nor can they explain how specific assignments arose from rudimentary differentiation between ancestral aaRSs and corresponding transfer RNAs (tRNAs). Experimental deconstruction of the two aaRS superfamilies created new experimental tools with which to analyze the emergence of the code. Amino acid and tRNA substrate recognition are linked to phase transfer free energies of amino acids and arise largely from aaRS class-specific differences in secondary structure. Sensitivity to protein folding rules endowed ancestral aaRS-tRNA pairs with the feedback necessary to rapidly compare alternative genetic codes and coding sequences. These and other experimental data suggest that the aaRS bidirectional genetic ancestry stabilized the differentiation and interdependence required to initiate and elaborate the genetic coding table.


Asunto(s)
Aminoacil-ARNt Sintetasas/genética , Aminoacil-ARNt Sintetasas/metabolismo , Evolución Molecular , Código Genético , Selección Genética , Aminoácidos/metabolismo , Aminoacil-ARNt Sintetasas/química , Catálisis , Genotipo , Fenotipo , Filogenia , Biosíntesis de Proteínas , Pliegue de Proteína , Estructura Secundaria de Proteína , ARN de Transferencia/genética , Termodinámica
8.
Annu Rev Biochem ; 90: 375-401, 2021 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-33441035

RESUMEN

Codon usage bias, the preference for certain synonymous codons, is found in all genomes. Although synonymous mutations were previously thought to be silent, a large body of evidence has demonstrated that codon usage can play major roles in determining gene expression levels and protein structures. Codon usage influences translation elongation speed and regulates translation efficiency and accuracy. Adaptation of codon usage to tRNA expression determines the proteome landscape. In addition, codon usage biases result in nonuniform ribosome decoding rates on mRNAs, which in turn influence the cotranslational protein folding process that is critical for protein function in diverse biological processes. Conserved genome-wide correlations have also been found between codon usage and protein structures. Furthermore, codon usage is a major determinant of mRNA levels through translation-dependent effects on mRNA decay and translation-independent effects on transcriptional and posttranscriptional processes. Here, we discuss the multifaceted roles and mechanisms of codon usage in different gene regulatory processes.


Asunto(s)
Uso de Codones , Expresión Génica , Biosíntesis de Proteínas , Pliegue de Proteína , Animales , Eucariontes/genética , Humanos , ARN Mensajero/genética , ARN Mensajero/metabolismo , ARN de Transferencia/genética , ARN de Transferencia/metabolismo , Ribosomas/genética , Ribosomas/metabolismo
9.
Annu Rev Biochem ; 89: 1-19, 2020 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-32343910

RESUMEN

It is impossible to do justice in one review article to a researcher of the stature of Christopher Dobson. His career spanned almost five decades, resulting in more than 870 publications and a legacy that will continue to influence the lives of many for decades to come. In this review, I have attempted to capture Chris's major contributions: his early work, dedicated to understanding protein-folding mechanisms; his collaborative work with physicists to understand the process of protein aggregation; and finally, his later career in which he developed strategies to prevent misfolding. However, it is not only this body of work but also the man himself who inspired an entire generation of scientists through his patience, ability to mentor, and innate generosity. These qualities remain a hallmark of the way in which he conducted his research-research that will leave a lasting imprint on science.

10.
Annu Rev Biochem ; 89: 443-470, 2020 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-32569525

RESUMEN

Manipulation of individual molecules with optical tweezers provides a powerful means of interrogating the structure and folding of proteins. Mechanical force is not only a relevant quantity in cellular protein folding and function, but also a convenient parameter for biophysical folding studies. Optical tweezers offer precise control in the force range relevant for protein folding and unfolding, from which single-molecule kinetic and thermodynamic information about these processes can be extracted. In this review, we describe both physical principles and practical aspects of optical tweezers measurements and discuss recent advances in the use of this technique for the study of protein folding. In particular, we describe the characterization of folding energy landscapes at high resolution, studies of structurally complex multidomain proteins, folding in the presence of chaperones, and the ability to investigate real-time cotranslational folding of a polypeptide.


Asunto(s)
Escherichia coli/genética , Chaperonas Moleculares/genética , Pinzas Ópticas , Biosíntesis de Proteínas , Proteoma/química , Ribosomas/genética , Escherichia coli/metabolismo , Humanos , Cinética , Microscopía de Fuerza Atómica , Modelos Moleculares , Chaperonas Moleculares/química , Chaperonas Moleculares/metabolismo , Unión Proteica , Pliegue de Proteína , Dominios y Motivos de Interacción de Proteínas , Proteoma/biosíntesis , Proteoma/genética , Proteostasis/genética , Ribosomas/metabolismo , Ribosomas/ultraestructura , Termodinámica
11.
Annu Rev Biochem ; 89: 21-43, 2020 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-32569520

RESUMEN

My coworkers and I have used animal viruses and their interaction with host cells to investigate cellular processes difficult to study by other means. This approach has allowed us to branch out in many directions, including membrane protein characterization, endocytosis, secretion, protein folding, quality control, and glycobiology. At the same time, our aim has been to employ cell biological approaches to expand the fundamental understanding of animal viruses and their pathogenic lifestyles. We have studied mechanisms of host cell entry and the uncoating of incoming viruses as well as the synthesis, folding, maturation, and intracellular movement of viral proteins and molecular assemblies. I have had the privilege to work in institutions in four different countries. The early years in Finland (the University of Helsinki) were followed by 6 years in Germany (European Molecular Biology Laboratory), 16 years in the United States (Yale School of Medicine), and 16 years in Switzerland (ETH Zurich).


Asunto(s)
Calnexina/genética , Calreticulina/genética , Interacciones Huésped-Patógeno/genética , Virus de la Influenza A/genética , Picornaviridae/genética , Proteínas Virales/genética , Virología/historia , Animales , Calnexina/química , Calnexina/metabolismo , Calreticulina/química , Calreticulina/metabolismo , Línea Celular , Retículo Endoplásmico/metabolismo , Retículo Endoplásmico/virología , Endosomas/metabolismo , Endosomas/virología , Regulación de la Expresión Génica , Historia del Siglo XX , Historia del Siglo XXI , Humanos , Virus de la Influenza A/metabolismo , Picornaviridae/metabolismo , Pliegue de Proteína , Virus de los Bosques Semliki/genética , Virus de los Bosques Semliki/metabolismo , Vesiculovirus/genética , Vesiculovirus/metabolismo , Proteínas Virales/química , Proteínas Virales/metabolismo , Internalización del Virus
12.
Annu Rev Biochem ; 89: 529-555, 2020 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-32097570

RESUMEN

Protein folding in the cell is mediated by an extensive network of >1,000 chaperones, quality control factors, and trafficking mechanisms collectively termed the proteostasis network. While the components and organization of this network are generally well established, our understanding of how protein-folding problems are identified, how the network components integrate to successfully address challenges, and what types of biophysical issues each proteostasis network component is capable of addressing remains immature. We describe a chemical biology-informed framework for studying cellular proteostasis that relies on selection of interesting protein-folding problems and precise researcher control of proteostasis network composition and activities. By combining these methods with multifaceted strategies to monitor protein folding, degradation, trafficking, and aggregation in cells, researchers continue to rapidly generate new insights into cellular proteostasis.


Asunto(s)
Chaperonas Moleculares/genética , Técnicas de Sonda Molecular , Proteoma/genética , Deficiencias en la Proteostasis/genética , Proteostasis/genética , Animales , Sistemas CRISPR-Cas , Regulación de la Expresión Génica , Semivida , Respuesta al Choque Térmico/efectos de los fármacos , Humanos , Chaperonas Moleculares/metabolismo , Agregado de Proteínas , Ingeniería de Proteínas/métodos , Pliegue de Proteína/efectos de los fármacos , Transporte de Proteínas/efectos de los fármacos , Proteoma/química , Proteoma/metabolismo , Proteostasis/efectos de los fármacos , Deficiencias en la Proteostasis/metabolismo , Deficiencias en la Proteostasis/patología , Transducción de Señal , Bibliotecas de Moléculas Pequeñas/síntesis química , Bibliotecas de Moléculas Pequeñas/farmacología , Respuesta de Proteína Desplegada/efectos de los fármacos
13.
Annu Rev Biochem ; 89: 389-415, 2020 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-32569518

RESUMEN

Folding of polypeptides begins during their synthesis on ribosomes. This process has evolved as a means for the cell to maintain proteostasis, by mitigating the risk of protein misfolding and aggregation. The capacity to now depict this cellular feat at increasingly higher resolution is providing insight into the mechanistic determinants that promote successful folding. Emerging from these studies is the intimate interplay between protein translation and folding, and within this the ribosome particle is the key player. Its unique structural properties provide a specialized scaffold against which nascent polypeptides can begin to form structure in a highly coordinated, co-translational manner. Here, we examine how, as a macromolecular machine, the ribosome modulates the intrinsic dynamic properties of emerging nascent polypeptide chains and guides them toward their biologically active structures.


Asunto(s)
Escherichia coli/genética , Chaperonas Moleculares/genética , Biosíntesis de Proteínas , Proteoma/química , Ribosomas/genética , Microscopía por Crioelectrón , Escherichia coli/metabolismo , Humanos , Espectroscopía de Resonancia Magnética , Modelos Moleculares , Chaperonas Moleculares/química , Chaperonas Moleculares/metabolismo , Unión Proteica , Pliegue de Proteína , Dominios y Motivos de Interacción de Proteínas , Proteoma/biosíntesis , Proteoma/genética , Proteostasis/genética , Deficiencias en la Proteostasis/genética , Deficiencias en la Proteostasis/metabolismo , Deficiencias en la Proteostasis/patología , Ribosomas/metabolismo , Ribosomas/ultraestructura
14.
Annu Rev Biochem ; 88: 337-364, 2019 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-30508494

RESUMEN

The timely production of functional proteins is of critical importance for the biological activity of cells. To reach the functional state, newly synthesized polypeptides have to become enzymatically processed, folded, and assembled into oligomeric complexes and, for noncytosolic proteins, translocated across membranes. Key activities of these processes occur cotranslationally, assisted by a network of machineries that transiently engage nascent polypeptides at distinct phases of translation. The sequence of events is tuned by intrinsic features of the nascent polypeptides and timely association of factors with the translating ribosome. Considering the dynamics of translation, the heterogeneity of cellular proteins, and the diversity of interaction partners, it is a major cellular achievement that these processes are temporally and spatially so precisely coordinated, minimizing the generation of damaged proteins. This review summarizes the current progress we have made toward a comprehensive understanding of the cotranslational interactions of nascent chains, which pave the way to their functional state.


Asunto(s)
Chaperonas Moleculares/metabolismo , Biosíntesis de Proteínas , Pliegue de Proteína , Ribosomas/metabolismo , Bacterias/genética , Bacterias/metabolismo , Eucariontes/genética , Eucariontes/metabolismo
15.
Cell ; 173(1): 62-73.e9, 2018 03 22.
Artículo en Inglés | MEDLINE | ID: mdl-29526462

RESUMEN

Aggregates of human islet amyloid polypeptide (IAPP) in the pancreas of patients with type 2 diabetes (T2D) are thought to contribute to ß cell dysfunction and death. To understand how IAPP harms cells and how this might be overcome, we created a yeast model of IAPP toxicity. Ste24, an evolutionarily conserved protease that was recently reported to degrade peptides stuck within the translocon between the cytoplasm and the endoplasmic reticulum, was the strongest suppressor of IAPP toxicity. By testing variants of the human homolog, ZMPSTE24, with varying activity levels, the rescue of IAPP toxicity proved to be directly proportional to the declogging efficiency. Clinically relevant ZMPSTE24 variants identified in the largest database of exomes sequences derived from T2D patients were characterized using the yeast model, revealing 14 partial loss-of-function variants, which were enriched among diabetes patients over 2-fold. Thus, clogging of the translocon by IAPP oligomers may contribute to ß cell failure.


Asunto(s)
Polipéptido Amiloide de los Islotes Pancreáticos/metabolismo , Proteínas de la Membrana/metabolismo , Metaloendopeptidasas/metabolismo , Diabetes Mellitus Tipo 2/metabolismo , Diabetes Mellitus Tipo 2/patología , Estrés del Retículo Endoplásmico/efectos de los fármacos , Humanos , Polipéptido Amiloide de los Islotes Pancreáticos/química , Polipéptido Amiloide de los Islotes Pancreáticos/toxicidad , Proteínas de la Membrana/química , Proteínas de la Membrana/genética , Metaloendopeptidasas/química , Metaloendopeptidasas/genética , Modelos Biológicos , Mutagénesis , Agregado de Proteínas/fisiología , Estructura Terciaria de Proteína , Saccharomyces cerevisiae/genética , Saccharomyces cerevisiae/metabolismo , Proteínas de Saccharomyces cerevisiae/genética , Proteínas de Saccharomyces cerevisiae/metabolismo , Respuesta de Proteína Desplegada/efectos de los fármacos
16.
Cell ; 172(3): 605-617.e11, 2018 01 25.
Artículo en Inglés | MEDLINE | ID: mdl-29336887

RESUMEN

The bacterial chaperonin GroEL and its cofactor, GroES, form a nano-cage for a single molecule of substrate protein (SP) to fold in isolation. GroEL and GroES undergo an ATP-regulated interaction cycle to close and open the folding cage. GroEL consists of two heptameric rings stacked back to back. Here, we show that GroEL undergoes transient ring separation, resulting in ring exchange between complexes. Ring separation occurs upon ATP-binding to the trans ring of the asymmetric GroEL:7ADP:GroES complex in the presence or absence of SP and is a consequence of inter-ring negative allostery. We find that a GroEL mutant unable to perform ring separation is folding active but populates symmetric GroEL:GroES2 complexes, where both GroEL rings function simultaneously rather than sequentially. As a consequence, SP binding and release from the folding chamber is inefficient, and E. coli growth is impaired. We suggest that transient ring separation is an integral part of the chaperonin mechanism.


Asunto(s)
Chaperonina 60/metabolismo , Adenosina Trifosfato/metabolismo , Animales , Chaperonina 10/metabolismo , Chaperonina 60/química , Chaperonina 60/genética , Mutación , Unión Proteica
17.
Annu Rev Biochem ; 86: 21-26, 2017 06 20.
Artículo en Inglés | MEDLINE | ID: mdl-28441058

RESUMEN

The majority of protein molecules must fold into defined three-dimensional structures to acquire functional activity. However, protein chains can adopt a multitude of conformational states, and their biologically active conformation is often only marginally stable. Metastable proteins tend to populate misfolded species that are prone to forming toxic aggregates, including soluble oligomers and fibrillar amyloid deposits, which are linked with neurodegeneration in Alzheimer and Parkinson disease, and many other pathologies. To prevent or regulate protein aggregation, all cells contain an extensive protein homeostasis (or proteostasis) network comprising molecular chaperones and other factors. These defense systems tend to decline during aging, facilitating the manifestation of aggregate deposition diseases. This volume of the Annual Review of Biochemistry contains a set of three articles addressing our current understanding of the structures of pathological protein aggregates and their associated disease mechanisms. These articles also discuss recent insights into the strategies cells have evolved to neutralize toxic aggregates by sequestering them in specific cellular locations.


Asunto(s)
Envejecimiento/metabolismo , Enfermedad de Alzheimer/metabolismo , Enfermedad de Parkinson/metabolismo , Agregación Patológica de Proteínas/metabolismo , Deficiencias en la Proteostasis/metabolismo , Envejecimiento/genética , Envejecimiento/patología , Enfermedad de Alzheimer/genética , Enfermedad de Alzheimer/patología , Amiloide/química , Amiloide/genética , Amiloide/metabolismo , Regulación de la Expresión Génica , Humanos , Chaperonas Moleculares/genética , Chaperonas Moleculares/metabolismo , Enfermedad de Parkinson/genética , Enfermedad de Parkinson/patología , Agregación Patológica de Proteínas/genética , Agregación Patológica de Proteínas/patología , Conformación Proteica , Pliegue de Proteína , Deficiencias en la Proteostasis/genética , Deficiencias en la Proteostasis/patología
18.
Cell ; 171(2): 346-357.e12, 2017 Oct 05.
Artículo en Inglés | MEDLINE | ID: mdl-28919078

RESUMEN

Newly synthesized proteins engage molecular chaperones that assist folding. Their progress is monitored by quality control systems that target folding errors for degradation. Paradoxically, chaperones that promote folding also direct unfolded polypeptides for degradation. Hence, a mechanism was previously hypothesized that prevents the degradation of actively folding polypeptides. In this study, we show that a conserved endoplasmic reticulum (ER) membrane protein complex, consisting of Slp1 and Emp65 proteins, performs this function in the ER lumen. The complex binds unfolded proteins and protects them from degradation during folding. In its absence, approximately 20%-30% of newly synthesized proteins that could otherwise fold are degraded. Although the Slp1-Emp65 complex hosts a broad range of clients, it is specific for soluble proteins. Taken together, these studies demonstrate the vulnerability of newly translated, actively folding polypeptides and the discovery of a new proteostasis functional class we term "guardian" that protects them from degradation.


Asunto(s)
Retículo Endoplásmico/metabolismo , Pliegue de Proteína , Proteínas de Saccharomyces cerevisiae/metabolismo , Saccharomyces cerevisiae/metabolismo , Proteínas de Transporte Vesicular/metabolismo , Animales , Degradación Asociada con el Retículo Endoplásmico , Glicosilación , Ratones , Chaperonas Moleculares/metabolismo , Proteolisis , Saccharomyces cerevisiae/citología , Proteínas de Saccharomyces cerevisiae/química , Proteínas de Transporte Vesicular/química
19.
Cell ; 171(7): 1625-1637.e13, 2017 Dec 14.
Artículo en Inglés | MEDLINE | ID: mdl-29198525

RESUMEN

When unfolded proteins accumulate in the endoplasmic reticulum (ER), the unfolded protein response (UPR) increases ER-protein-folding capacity to restore protein-folding homeostasis. Unfolded proteins activate UPR signaling across the ER membrane to the nucleus by promoting oligomerization of IRE1, a conserved transmembrane ER stress receptor. However, the coupling of ER stress to IRE1 oligomerization and activation has remained obscure. Here, we report that the ER luminal co-chaperone ERdj4/DNAJB9 is a selective IRE1 repressor that promotes a complex between the luminal Hsp70 BiP and the luminal stress-sensing domain of IRE1α (IRE1LD). In vitro, ERdj4 is required for complex formation between BiP and IRE1LD. ERdj4 associates with IRE1LD and recruits BiP through the stimulation of ATP hydrolysis, forcibly disrupting IRE1 dimers. Unfolded proteins compete for BiP and restore IRE1LD to its default, dimeric, and active state. These observations establish BiP and its J domain co-chaperones as key regulators of the UPR.


Asunto(s)
Endorribonucleasas/metabolismo , Proteínas del Choque Térmico HSP40/metabolismo , Proteínas de Choque Térmico/metabolismo , Proteínas de la Membrana/metabolismo , Chaperonas Moleculares/metabolismo , Proteínas Serina-Treonina Quinasas/metabolismo , Respuesta de Proteína Desplegada , Animales , Cricetinae , Retículo Endoplásmico/metabolismo , Chaperón BiP del Retículo Endoplásmico , Humanos , Pliegue de Proteína
20.
Mol Cell ; 84(13): 2455-2471.e8, 2024 Jul 11.
Artículo en Inglés | MEDLINE | ID: mdl-38908370

RESUMEN

Protein folding is assisted by molecular chaperones that bind nascent polypeptides during mRNA translation. Several structurally distinct classes of chaperones promote de novo folding, suggesting that their activities are coordinated at the ribosome. We used biochemical reconstitution and structural proteomics to explore the molecular basis for cotranslational chaperone action in bacteria. We found that chaperone binding is disfavored close to the ribosome, allowing folding to precede chaperone recruitment. Trigger factor recognizes compact folding intermediates that expose an extensive unfolded surface, and dictates DnaJ access to nascent chains. DnaJ uses a large surface to bind structurally diverse intermediates and recruits DnaK to sequence-diverse solvent-accessible sites. Neither Trigger factor, DnaJ, nor DnaK destabilize cotranslational folding intermediates. Instead, the chaperones collaborate to protect incipient structure in the nascent polypeptide well beyond the ribosome exit tunnel. Our findings show how the chaperone network selects and modulates cotranslational folding intermediates.


Asunto(s)
Proteínas de Escherichia coli , Escherichia coli , Proteínas del Choque Térmico HSP40 , Proteínas HSP70 de Choque Térmico , Biosíntesis de Proteínas , Pliegue de Proteína , Ribosomas , Ribosomas/metabolismo , Ribosomas/genética , Proteínas de Escherichia coli/metabolismo , Proteínas de Escherichia coli/genética , Proteínas de Escherichia coli/química , Proteínas HSP70 de Choque Térmico/metabolismo , Proteínas HSP70 de Choque Térmico/genética , Proteínas del Choque Térmico HSP40/metabolismo , Proteínas del Choque Térmico HSP40/genética , Escherichia coli/metabolismo , Escherichia coli/genética , Unión Proteica , Chaperonas Moleculares/metabolismo , Chaperonas Moleculares/genética , Modelos Moleculares , Conformación Proteica , Isomerasa de Peptidilprolil
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