The structural biology of the dynamin‐related proteins: New insights into a diverse,multitalented family

Dynamin‐related proteins are multidomain, mechanochemical GTPases that self‐assemble and orchestrate a wide array of cellular processes. Over the past decade, structural insights from X‐ray crystallography and cryo‐electron microscopy have reshaped our mechanistic understanding of these proteins. Here, we provide a historical perspective on these advances that highlights the structural attributes of different dynamin family members and explores how these characteristics affect GTP hydrolysis, conformational coupling and oligomerization. We also discuss a number of lingering challenges remaining in the field that suggest future directions of study.     

固氮酶晶体学研究进展

生物大分子的功能取决于它的空间结构。X射线衍射分析是获得生物大分子结构信息的常用方法。本文对固氮酶晶体的生长及其X射线衍射分析的主要进展简要地进行了介绍和评论。最后展望了今后的发展及问题。     

固氮酶晶体学研究进展

生物大分子的功能取决于它的空间结构.X射线衍射分析是获得生物大分子结构信息的常用方法.本文对固氮酶晶体的生长及其X射线衍射分析的主要进展简要地进行了介绍和评论.最后展望了今后的发展及问题.     

What transmission electron microscopes can visualize now and in the future

Our review concentrates on the progress made in high-resolution transmission electron microscopy (TEM) in the past decade. This includes significant improvements in sample preparation by quick-freezing aimed at preserving the specimen in a close-to-native state in the high vacuum of the microscope. Following advances in cold stage and TEM vacuum technology systems, the observation of native, frozen hydrated specimens has become a widely used approach. It fostered the development of computer guided, fully automated low-dose data acquisition systems allowing matched pairs of images and diffraction patterns to be recorded for electron crystallography, and the collection of entire tilt-series for electron tomography. To achieve optimal information transfer to atomic resolution, field emission electron guns combined with acceleration voltages of 200-300 kV are now routinely used. The outcome of these advances is illustrated by the atomic structure of mammalian aquaporin-O and by the pore-forming bacterial cytotoxin ClyA resolved to 12 A. Further, the Yersinia injectisome needle, a bacterial pseudopilus and the binding of phalloidin to muscle actin filaments were chosen to document the advantage of the high contrast offered by dedicated scanning transmission electron microscopy (STEM) and/or the STEM's ability to measure the mass of protein complexes and directly link this to their shape. Continued progress emerging from leading research laboratories and microscope manufacturers will eventually enable us to determine the proteome of a single cell by electron tomography, and to more routinely solve the atomic structure of membrane proteins by electron crystallography.     

High-throughput protein crystallization

The combinatorial chemistry industry has made major advances in the handling and mixing of small volumes, and in the development of robust liquid-handling systems. In addition, developments have been made in the area of material handling for the high-throughput drug screening and combinatorial chemistry fields. Lastly, improvements in beamline optics at synchrotron sources have enabled the use of flash-frozen micron-sized (10-50 microm) crystals. The combination of these and other recent advances will make high-throughput protein crystallography possible. Further advances in high-throughput methods of protein crystallography will require application of the above developments and the accumulation of success/failure data in a more systematic manner. Major changes in crystallography technology will emerge based on the data collected by first-generation high-throughput systems.     

A virtual high-throughput screening approach to the discovery of novel inhibitors of the bacterial leucine transporter,LeuT

Abstract

Membrane proteins are intrinsically involved in both human and pathogen physiology, and are the target of 60% of all marketed drugs. During the past decade, advances in the studies of membrane proteins using X-ray crystallography, electron microscopy and NMR-based techniques led to the elucidation of over 250 unique membrane protein crystal structures. The aim of the European Drug Initiative for Channels and Transporter (EDICT) project is to use the structures of clinically significant membrane proteins for the development of lead molecules. One of the approaches used to achieve this is a virtual high-throughput screening (vHTS) technique initially developed for soluble proteins. This paper describes application of this technique to the discovery of inhibitors of the leucine transporter (LeuT), a member of the neurotransmitter:sodium symporter (NSS) family.     

X-ray crystallography of chemical compounds

AimsAccurate knowledge of molecular structure is a prerequisite for rational drug design. This review examines the role of X-ray crystallography in providing the required structural information and advances in the field of X-ray crystallography that enhance or expand its role.Main methodsX-ray crystallography of new drugs candidates and intermediates can provide valuable information of new syntheses and parameters for quantitative structure activity relationships (QSAR).Key findingsCrystallographic studies play a vital role in many disciplines including materials science, chemistry, pharmacology, and molecular biology. X-ray crystallography is the most comprehensive technique available to determine molecular structure. A requirement for the high accuracy of crystallographic structures is that a ‘good crystal’ must be found, and this is often the rate-limiting step. In the past three decades developments in detectors, increases in computer power, and powerful graphics capabilities have contributed to a dramatic increase in the number of materials characterized by X-ray crystallography. More recently the advent of high-throughput crystallization techniques has enhanced our ability to produce that one good crystal required for crystallographic analysis.SignificanceContinuing advances in all phases of a crystallographic study have expanded the ranges of samples which can be analyzes by X-ray crystallography to include larger molecules, smaller or weakly diffracting crystals, and twinned crystals.     

Frontiers in metalloprotein crystallography and cryogenic electron microscopy

Metalloproteins comprise at least a third of all proteins that utilize redox properties of transition metals on their own or as parts of cofactors. The development of third generation storage ring sources and X-ray free-electron lasers with femtosecond pulses in the first decade of the 21st century has transformed metalloprotein crystallography. In the past decade, cryogenic-electron microscopy single-particle analysis, which does not require crystallization of biological samples has been extensively utilized, particularly for membrane-bound metalloprotein systems. Here, we explore recent frontiers in metalloprotein crystallography and cryogenic electron microscopy, organized for convenience under three metalloprotein-centered biological cycles, focusing on contributions from each technique, their synergy and the ability to preserve metals’ redox states when subjected to a particular probe.     

细菌分泌系统的结构及作用机制研究进展

细菌分泌系统（bacterial secretion systems）是一类存在于细菌细胞膜上的大分子复合物，是结构复杂的跨膜分子机器，可为多种细菌的效应物提供分泌途径。目前已经发现了9种细菌分泌系统，即T1SS~T9SS，在细菌的生存及致病力方面发挥着重要作用。随着X射线晶体学（X-ray crystallography）、核磁共振（nuclear magnetic resonance，NMR）及冷冻电镜（cryo-electron microscopy，Cryo-EM）等技术手段的发展与应用，这些大分子复合物的三维结构也得到了一定程度的解析，极大增强了人类对于细菌分泌系统转运底物复杂机制的理解。因此，本文结合近年来关于细菌T1SS~T9SS的研究进展，对各分泌系统的结构信息进行了系统整合，总结了这些分泌系统的分子作用机制，并对其未来的发展方向进行了展望，以期为与细菌蛋白质分泌相关的致病、耐药、环境适应性等机制的研究奠定理论基础，为进一步开发以分泌系统结构为基础的小分子抑菌物质提供精准的三维靶标。     

Advances in Structural Biology and the Application to Biological Filament Systems

Structural biology has experienced several transformative technological advances in recent years. These include: development of extremely bright X‐ray sources (microfocus synchrotron beamlines and free electron lasers) and the use of electrons to extend protein crystallography to ever decreasing crystal sizes; and an increase in the resolution attainable by cryo‐electron microscopy. Here we discuss the use of these techniques in general terms and highlight their application for biological filament systems, an area that is severely underrepresented in atomic resolution structures. We assemble a model of a capped tropomyosin‐actin minifilament to demonstrate the utility of combining structures determined by different techniques. Finally, we survey the methods that attempt to transform high resolution structural biology into more physiological environments, such as the cell. Together these techniques promise a compelling decade for structural biology and, more importantly, they will provide exciting discoveries in understanding the designs and purposes of biological machines.     

Structure and mechanics of integrin-based cell adhesion

Integrins are alpha/beta heterodimeric adhesion glycoprotein receptors that regulate a wide variety of dynamic cellular processes such as cell migration, phagocytosis, and growth and development. X-ray crystallography of the integrin ectodomain revealed its modular architecture and defined its metal-dependent interaction with extracellular ligands. This interaction is regulated from inside the cell (inside-out activation), through the short cytoplasmic alpha and beta integrin tails, which also mediate biochemical and mechanical signals transmitted to the cytoskeleton by the ligand-occupied integrins, effecting major changes in cell shape, behavior, and fate. Recent advances in the structural elucidation of integrins and integrin-binding cytoskeleton proteins are the subjects of this review.     

Systematic Deciphering of Cancer Genome Networks

When growth regulatory genes are damaged in a cell, it may become cancerous. Current technological advances in the last decade have allowed the characterization of the whole genome of these cells by directly or indirectly measuring DNA changes. Complementary analyses were developed to make sense of the massive amounts of data generated. A large majority of these analyses were developed to construct interaction networks between genes from, primarily, expression array data. We review the current technologies and analyses that have developed in the last decade. We further argue that as cancer genomics evolves from single gene validations to gene network inferences, new analyses must be developed for the different technological platforms.     

New structural snapshots provide molecular insights into the mechanism of high fidelity DNA synthesis

Time-lapse X-ray crystallography allows visualization of intermediate structures during the DNA polymerase catalytic cycle. Employing time-lapse crystallography with human DNA polymerase β has recently allowed us to capture and solve novel intermediate structures that are not stable enough to be analyzed by traditional crystallography. The structures of these intermediates reveals exciting surprises about active site metal ions and enzyme conformational changes as the reaction proceeds from the ground state to product release. In this perspective, we provide an overview of recent advances in understanding the DNA polymerase nucleotidyl transferase reaction and highlight both the significance and mysteries of enzyme efficiency and specificity that remain to be solved.     

Applications à la conchyliculture des récentes acquisitions sur la biologie des mollusques bivalves

Today, mollusc farming represents the fourth part of the mundial aquaculture production. These results have been permitted by the improvement of farming techniques commercially important but also by advances in the biology of a species. Valuable reproductive studies have been carried out in s.a. hatcheries on triploids and tetraploids animals. Since the last decade, advances in the knowledge of metabolism and growth mechanisms has helped the improvement of the brood stock. Nevertheless, the mundial expansion of bivalve farming increases the outbreak of strong epizooties. Investigations allow a valuable knowledge on the scope of molluscan defence mechanisms against pathogen agents. The results are discussed in relation to a possible selection for bivalve farming.     

mTOR regulation of autophagy

Nutrient starvation induces autophagy in eukaryotic cells through inhibition of TOR (target of rapamycin), an evolutionarily-conserved protein kinase. TOR, as a central regulator of cell growth, plays a key role at the interface of the pathways that coordinately regulate the balance between cell growth and autophagy in response to nutritional status, growth factor and stress signals. Although TOR has been known as a key regulator of autophagy for more than a decade, the underlying regulatory mechanisms have not been clearly understood. This review discusses the recent advances in understanding of the mechanism by which TOR regulates autophagy with focus on mammalian TOR (mTOR) and its regulation of the autophagy machinery.     

Combining on-line spectroscopy with synchrotron and X-ray free electron laser crystallography

With the recent advances in serial crystallography methods at both synchrotron and X-ray free electron laser sources, more details of intermediate or transient states of the catalytic reactions are being revealed structurally. These structural studies of reaction dynamics drive the need for on-line in crystallo spectroscopy methods to complement the crystallography experiment. The recent applications of combined spectroscopy and crystallography methods enable on-line determination of in crystallo reaction kinetics and structures of catalytic intermediates, sample integrity, and radiation-induced sample modifications, if any, as well as heterogeneity of crystals from different preparations or sample batches. This review describes different modes of spectroscopy that are combined with the crystallography experiment at both synchrotron and X-ray free-electron laser facilities, and the complementary information that each method can provide to facilitate the structural study of enzyme catalysis and protein dynamics.     

A Maltose-Binding Protein Fusion Construct Yields a Robust Crystallography Platform for MCL1

Crystallization of a maltose-binding protein MCL1 fusion has yielded a robust crystallography platform that generated the first apo MCL1 crystal structure, as well as five ligand-bound structures. The ability to obtain fragment-bound structures advances structure-based drug design efforts that, despite considerable effort, had previously been intractable by crystallography. In the ligand-independent crystal form we identify inhibitor binding modes not observed in earlier crystallographic systems. This MBP-MCL1 construct dramatically improves the structural understanding of well-validated MCL1 ligands, and will likely catalyze the structure-based optimization of high affinity MCL1 inhibitors.     

Structural insights into the Type II secretion nanomachine

The Type II secretion nanomachine transports folded proteins across the outer membrane of Gram-negative bacteria. Recent X-ray crystallography, electron microscopy, and molecular modeling studies provide structural insights into three functionally and spatially connected units of this nanomachine: the cytoplasmic and inner membrane energy-harvesting complex, the periplasmic helical pseudopilus, and the outer membrane secretin. Key advances include cryo-EM reconstruction of the secretin and demonstration that it interacts with both secreted substrates and a crucial transmembrane clamp protein, plus a biochemical and structural explanation of the role of low-abundance pseudopilins in initiating pseudopilus growth. Combining structures and protein interactions, we synthesize a 3D view of the complete complex consistent with a stepwise pathway in which secretin oligomerization defines sites of nanomachine biogenesis.     

Structures and recognition modes of toll‐like receptors

Toll‐like receptors (TLRs) recognize common structural patterns in diverse microbial molecules and play central roles in the innate immune response. The structures of extracellular domains and their ligand complexes of several TLRs have been determined by X‐ray crystallography. Here, we discuss recent advances on structures and activation mechanisms of TLRs. Despite the differences in interaction areas of ligand with TLRs, the extracellular domains of TLRs all adopt horseshoe‐shaped structures and the overall M‐shape of the TLR–ligand complexes is strikingly similar. The structural rearrangement information of TLRs sheds new light on their ligand‐recognition and ‐activation mechanisms. Proteins 2016; 85:3–9. © 2016 Wiley Periodicals, Inc.     

Detergent quantification in membrane protein samples and its application to crystallization experiments

The structural characterization of membrane proteins remains a challenging field, largely because the use of stabilizing detergents is required. Researchers must first select a suitable detergent for the solubility and stability of their protein during in vitro studies. In addition, an appropriate concentration of detergent in membrane protein samples can be essential for protein solubility, stability, and experimental success. For example, in membrane protein crystallography, detergent concentration in the crystallization drop can be a critical parameter influencing crystal growth. Over the past decade, multiple techniques have been developed for the measurement of detergent concentration using a wide variety of strategies. These methods include colorimetric reactions, which target specific detergent classes, and analytical techniques applicable to a wide variety of detergents. This review will summarize and discuss the available options. It will be a useful resource to those selecting a strategy that best fits their experimental requirements and available instruments.