Your search keyword '"Brent L. Nannenga"' showing total 16 results

1. Electron-counting MicroED data with the K2 and K3 direct electron detectors

Author

Max T.B. Clabbers, Michael W. Martynowycz, Johan Hattne, Brent L. Nannenga, and Tamir Gonen

Subjects

Structural Biology, Electrons

Abstract

Microcrystal electron diffraction (MicroED) uses electron cryo-microscopy (cryo-EM) to collect diffraction data from small crystals during continuous rotation of the sample. As a result of advances in hardware as well as methods development, the data quality has continuously improved over the past decade, to the point where even macromolecular structures can be determined ab initio. Detectors suitable for electron diffraction should ideally have fast readout to record data in movie mode, and high sensitivity at low exposure rates to accurately report the intensities. Direct electron detectors are commonly used in cryo-EM imaging for their sensitivity and speed, but despite their availability are generally not used in diffraction. Primary concerns with diffraction experiments are the dynamic range and coincidence loss, which will corrupt the measurement if the flux exceeds the count rate of the detector. Here, we describe instrument setup and low-exposure MicroED data collection in electron-counting mode using K2 and K3 direct electron detectors and show that the integrated intensities can be effectively used to solve structures of two macromolecules between 1.2 Å and 2.8 Å. Even though a beam stop was not used in these studies we did not observe damage to the camera. As these cameras are already available in many cryo-EM facilities, this provides opportunities for users who do not have access to dedicated facilities for MicroED.

Published

2022

2. The complementarity of serial femtosecond crystallography and MicroED for structure determination from microcrystals

Author

Nadia A. Zatsepin, Paige Colasurd, Brent L. Nannenga, and Chufeng Li

Subjects

Free electron model, 0303 health sciences, Crystallography, Time Factors, Materials science, Protein dynamics, Resolution (electron density), Electrons, Electron, Laser, Article, law.invention, 03 medical and health sciences, 0302 clinical medicine, Electron diffraction, Structural Biology, law, Nano, Femtosecond, Molecular Biology, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

In recent years, nano and microcrystals have emerged as a valuable source of high-resolution structural information owing to the invention of serial femtosecond crystallography (SFX) with X-ray free electron lasers and microcrystal electron diffraction (MicroED) using electron cryomicroscopes. Once considered useless for structure determination, nano/microcrystals now confer significant advantages for static and time-resolved structure determination from a wide variety of difficult-to-study targets. MicroED has been used to obtain sub-Ångstrom resolution maps in which hydrogen atoms can be clearly resolved from only a few nano/microcrystals, while SFX has been used to probe protein dynamics following reaction initiation on time scales from femtoseconds to minutes. We review these two complementary techniques and their abilities for high-resolution structure determination.

Published

2019

3. MicroED Sample Preparation and Data Collection For Protein Crystals

Author

Brent L. Nannenga and Guanhong Bu

Subjects

0301 basic medicine, Diffraction, Materials science, macromolecular substances, 010403 inorganic & nuclear chemistry, 01 natural sciences, 0104 chemical sciences, Organic molecules, 03 medical and health sciences, Crystallography, 030104 developmental biology, Structural biology, Electron diffraction, X-ray crystallography, Sample preparation, Protein crystallization

Abstract

Microcrystal Electron Diffraction (MicroED) enables structure determination of very small crystals that are much too small to be of use for other conventional diffraction techniques. MicroED has been used to determine the structures of many proteins and small organic molecules, and the technique can be performed on most standard cryo-TEM instruments equipped with high-speed detectors capable of collecting electron diffraction data. Here, we present protocols for MicroED sample preparation and data collection for protein microcrystals.

Published

2020

4. Structural insights into the function of the catalytically active human Taspase1

Author

Brent L. Nannenga, James J. Hsieh, Jose M. Martin-Garcia, Nirupa Nagaratnam, Dewight Williams, Darren Thifault, Mary Stofega, Silvia Delker, Petra Fromme, Lidia Sambucetti, Rebecca Jernigan, Andrew Flint, Janey Snider, Thomas E. Edwards, National Cancer Institute (US), and National Institutes of Health (US)

Subjects

Models, Molecular, Proteases, Ntn-hydrolases, Cleavage (embryo), Intrinsically disordered proteins, Crystallography, X-Ray, Protein Structure, Secondary, Metastasis, 03 medical and health sciences, Protein Domains, Structural Biology, Plant-type L-asparaginases, Endopeptidases, medicine, Humans, Cloning, Molecular, Molecular Biology, 030304 developmental biology, Cancer, X-ray crystallography, Cloning, chemistry.chemical_classification, 0303 health sciences, 030302 biochemistry & molecular biology, medicine.disease, Dynamic Light Scattering, Cell biology, Enzyme Activation, Enzyme, chemistry, Taspase1, Anisotropy, Function (biology)

Abstract

19 pags., 7 figs., 2 tabs., Taspase1 is an Ntn-hydrolase overexpressed in primary human cancers, coordinating cancer cell proliferation, invasion, and metastasis. Loss of Taspase1 activity disrupts proliferation of human cancer cells in vitro and in mouse models of glioblastoma. Taspase1 is synthesized as an inactive proenzyme, becoming active upon intramolecular cleavage. The activation process changes the conformation of a long fragment at the C-terminus of the α subunit, for which no full-length structural information exists and whose function is poorly understood. We present a cloning strategy to generate a circularly permuted form of Taspase1 to determine the crystallographic structure of active Taspase1. We discovered that this region forms a long helix and is indispensable for the catalytic activity of Taspase1. Our study highlights the importance of this element for the enzymatic activity of Ntn-hydrolases, suggesting that it could be a potential target for the design of inhibitors with potential to be developed into anticancer therapeutics., This project has been funded in whole with Federal funds from the National Cancer Institute (NCI), National Institutes of Health (NIH), under Chemical Biology Consortium contract no. HHSN261200800001E.

Published

2020

5. Tetragonal crystal form of the cyanobacterial bicarbonate-transporter regulator SbtB from Synechocystis sp. PCC 6803

Author

Chad R. Simmons, Brent L. Nannenga, David R. Nielsen, and Guanhong Bu

Subjects

Models, Molecular, Protein Conformation, alpha-Helical, Stereochemistry, Anion Transport Proteins, Genetic Vectors, Biophysics, Gene Expression, Bicarbonate transporter protein, Trimer, Crystal structure, Crystallography, X-Ray, Biochemistry, Research Communications, Crystal, 03 medical and health sciences, Tetragonal crystal system, Tetramer, Bacterial Proteins, Structural Biology, Genetics, Escherichia coli, Protein Interaction Domains and Motifs, Amino Acid Sequence, Cloning, Molecular, 030304 developmental biology, 0303 health sciences, Binding Sites, biology, Chemistry, 030302 biochemistry & molecular biology, Synechocystis, Bicarbonate transport, Condensed Matter Physics, biology.organism_classification, Recombinant Proteins, Bicarbonates, Protein Conformation, beta-Strand, Protein Multimerization, Protein Binding

Abstract

The PII-like protein SbtB has been identified as a regulator of SbtA, which is one of the key bicarbonate transporters in cyanobacteria. While SbtB from Synechocystis sp. PCC 6803 has previously been shown to be a trimer, a new crystal form is reported here which crystallizes in what is thought to be a non-native tetramer in the crystal, with the C-terminus in an extended conformation. The crystal structure shows the formation of an intermolecular disulfide bond at Cys94 between SbtB monomers, which may stabilize this conformation in the crystal. This motivates the need for future studies to investigate the potential role that the oxidation and reduction of these cysteines may play in the activation and/or function of SbtB.

Published

2020

6. New structural insights into the function of the catalytically active human Taspase1

Author

Silvia Delker, Dewight Williams, Thomas E. Edwards, James J. Hsieh, Nirupa Nagaratnam, Andrew Flint, Janey Sneider, Rebecca Jernigan, Brent L. Nannenga, Jose M. Martin-Garcia, Mary Stofega, Lidia Sambucetti, and Darren Thifault

Subjects

Inorganic Chemistry, Structural Biology, Chemistry, Biophysics, General Materials Science, Physical and Theoretical Chemistry, Condensed Matter Physics, Biochemistry, Function (biology)

Published

2021

7. MicroED methodology and development

Author

Brent L. Nannenga

Subjects

Engineering, Materials science, Process management, Nanotechnology, 02 engineering and technology, 010403 inorganic & nuclear chemistry, 01 natural sciences, Biochemistry, Experimental Methodologies, Organic molecules, Inorganic Chemistry, ARTICLES, Development (topology), Structural Biology, 0103 physical sciences, lcsh:QD901-999, General Materials Science, Physical and Theoretical Chemistry, 010306 general physics, Instrumentation, Spectroscopy, Radiation, business.industry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Method development, 0104 chemical sciences, Electron diffraction, lcsh:Crystallography, 0210 nano-technology, business

Abstract

Microcrystal electron diffraction, or MicroED, is a method that is capable of determining structure from very small and thin 3D crystals using a transmission electron microscope. MicroED has been successfully used on microcrystalline samples, including proteins, peptides, and small organic molecules, in many cases to very high resolutions. In this work, the MicroED workflow will be briefly described and areas of future method development will be highlighted. These areas include improvements in sample preparation, data collection, and structure determination.

Published

2019

8. Structure determination from lipidic cubic phase embedded microcrystals by MicroED

Author

Brent L. Nannenga, Wei Liu, Liang Jing, Lan Zhu, Dan Shi, Tamir Gonen, and Guanhong Bu

Subjects

Diffraction, Model system, law.invention, Crystal, Glycols, 0302 clinical medicine, GPCR, Structural Biology, law, Phase (matter), microcrystal electron diffraction, Sample preparation, membrane protein, Microscopy, 0303 health sciences, 030302 biochemistry & molecular biology, Cholesterol crystals, Biological Sciences, Lipids, additive phase conversion, Cholesterol, Microcrystalline, Electron diffraction, Endopeptidase K, Crystallization, Receptor, microcrystallography, Materials science, Receptor, Adenosine A2A, Biophysics, cryo-electron microscopy, lipase hydrolysis, Electron, Adenosine A2A, 03 medical and health sciences, Microscopy, Electron, Transmission, Information and Computing Sciences, Transmission, Molecular Biology, 030304 developmental biology, Cryoelectron Microscopy, cholesterol, Proteinase K, Nanocrystal, Chemical engineering, Chemical Sciences, Nanoparticles, Electron microscope, lipidic cubic phase, 030217 neurology & neurosurgery

Abstract

The lipidic cubic phase (LCP) technique has proved to facilitate the growth of high-quality crystals that are otherwise difficult to grow by other methods. However, the crystal size optimization process could be time and resource consuming, if it ever happens. Therefore, improved techniques for structure determination using these small crystals is an important strategy in diffraction technology development. Microcrystal electron diffraction (MicroED) is a technique that uses a cryo-transmission electron microscopy to collect electron diffraction data and determine high-resolution structures from very thin micro- and nanocrystals. In this work, we have used modified LCP and MicroED protocols to analyze crystals embedded in LCP converted by 2-methyl-2,4-pentanediol or lipase, including Proteinase K crystals grown in solution, cholesterol crystals, and human adenosine A2A receptor crystals grown in LCP. These results set the stage for the use of MicroED to analyze microcrystalline samples grown in LCP, especially for those highly challenging membrane protein targets.

Published

2019

9. MicroED on lipidic cubic phase embedded crystals

Author

Brent L. Nannenga

Subjects

Inorganic Chemistry, Crystallography, Materials science, Structural Biology, Phase (matter), General Materials Science, Physical and Theoretical Chemistry, Condensed Matter Physics, Biochemistry

Published

2020

10. MicroED data collection and processing

Author

Andrew G. W. Leslie, Dan Shi, Johan Hattne, Francis E. Reyes, M. Jason de la Cruz, Tamir Gonen, and Brent L. Nannenga

Subjects

Diffraction, Cryo-electron microscopy, Nanotechnology, 02 engineering and technology, Crystallography, X-Ray, Biochemistry, Intersection (Euclidean geometry), Computational science, Inorganic Chemistry, 03 medical and health sciences, nanocrystals, Structural Biology, General Materials Science, Physical and Theoretical Chemistry, crystallography, 030304 developmental biology, Physics, 0303 health sciences, Crystallography, Data collection, Data Collection, Cryoelectron Microscopy, Resolution (electron density), Proteins, Limiting, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Feature Articles, Electron diffraction, X-Ray, cryo-EM, electron diffraction, Hardware_CONTROLSTRUCTURESANDMICROPROGRAMMING, 0210 nano-technology, MicroED

Abstract

The collection and processing of MicroED data are presented., MicroED, a method at the intersection of X-ray crystallography and electron cryo-microscopy, has rapidly progressed by exploiting advances in both fields and has already been successfully employed to determine the atomic structures of several proteins from sub-micron-sized, three-dimensional crystals. A major limiting factor in X-ray crystallography is the requirement for large and well ordered crystals. By permitting electron diffraction patterns to be collected from much smaller crystals, or even single well ordered domains of large crystals composed of several small mosaic blocks, MicroED has the potential to overcome the limiting size requirement and enable structural studies on difficult-to-crystallize samples. This communication details the steps for sample preparation, data collection and reduction necessary to obtain refined, high-resolution, three-dimensional models by MicroED, and presents some of its unique challenges.

Published

2015

11. Atomic structures of fibrillar segments of hIAPP suggest tightly mated beta-sheets are important or cytotoxicity

Author

David Eisenberg, Pascal Krotee, Stephan Philipp, Michael R. Sawaya, Jose A. Rodriguez, Tamir Gonen, Marie E. Oskarsson, Gunilla T. Westermark, Duilio Cascio, Sarah Griner, Dan Shi, Charles G. Glabe, Brent L. Nannenga, Francis E. Reyes, Johan Hattne, and Lin Jiang

Subjects

0301 basic medicine, Protein Conformation, Cell- och molekylärbiologi, Biochemistry, Type ii diabetes, Insulin-Secreting Cells, biophysics, amyloid fibril, Cytotoxic T cell, structural biology, Biology (General), Cytotoxicity, Cells, Cultured, Cultured, Chemistry, General Neuroscience, General Medicine, Biophysics and Structural Biology, Islet Amyloid Polypeptide, Cell and molecular biology, Endokrinologi och diabetes, Medicine, cytotoxicity, MicroED, Research Article, Human, Programmed cell death, Amyloid, QH301-705.5, Cell Survival, Science, Cells, Endocrinology and Diabetes, Fibril, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Type-II Diabetes, Humans, biochemistry, human, 030102 biochemistry & molecular biology, General Immunology and Microbiology, Cryoelectron Microscopy, 030104 developmental biology, Structural biology, Biophysics, Protein Conformation, beta-Strand, beta-Strand, Generic health relevance, Biochemistry and Cell Biology, Cell and Molecular Biology

Abstract

hIAPP fibrils are associated with Type-II Diabetes, but the link of hIAPP structure to islet cell death remains elusive. Here we observe that hIAPP fibrils are cytotoxic to cultured pancreatic β-cells, leading us to determine the structure and cytotoxicity of protein segments composing the amyloid spine of hIAPP. Using the cryoEM method MicroED, we discover that one segment, 19–29 S20G, forms pairs of β-sheets mated by a dry interface that share structural features with and are similarly cytotoxic to full-length hIAPP fibrils. In contrast, a second segment, 15–25 WT, forms non-toxic labile β-sheets. These segments possess different structures and cytotoxic effects, however, both can seed full-length hIAPP, and cause hIAPP to take on the cytotoxic and structural features of that segment. These results suggest that protein segment structures represent polymorphs of their parent protein and that segment 19–29 S20G may serve as a model for the toxic spine of hIAPP. DOI: http://dx.doi.org/10.7554/eLife.19273.001, eLife digest In Type-II Diabetes, an individual’s cells fail to respond correctly to the hormone insulin, leaving them unable to counteract high levels of sugar in the blood. Another hormone, human islet amyloid polypeptide (hIAPP), works with insulin to regulate blood sugar levels. hIAPP is an amyloid protein, which means that it can lose its normal structure and form fibrils. Fibrils are difficult for cells to break down and are often associated with disease. Indeed, fibrils of hIAPP often form in the pancreas as part of Type-II Diabetes. Some studies have shown that hIAPP fibrils are toxic to pancreatic cells and worsen the symptoms of Type-II Diabetes. Others suggest that it is the process of fibril formation that is toxic, not the fibrils themselves. Although the structures of the fibrils have been described, whether these structures cause cell toxicity has not been investigated. Krotee et al. have now explored the structures of two overlapping segments of hIAPP using a new cryo electron microscopy method called MicroED that is ideal for studying such segments. One segment, called 19-29 S20G, forms a standard amyloid fibril structure that is similar to the structure of full-length hIAPP fibrils. Adding these segments to human cells causes similar levels of toxicity as the full-length hIAPP fibrils. The second segment, called 15-25 WT, forms a non-toxic structure that is less stable than standard amyloid fibrils. The results presented by Krotee et al. support the view that standard amyloid fibril structures are toxic to cells and suggest that 19-29 S20G may be a good model to use when studying how full-length hIAPP fibrils behave. The structure of 19-29 S20G may also be useful as a template for designing molecules that block amyloid fibril growth. If amyloid fibrils cause cell toxicity in the pancreas, then these molecules could be used to treat Type-II Diabetes. DOI: http://dx.doi.org/10.7554/eLife.19273.002

Published

2017

12. Structure determination by microcrystal electron diffraction

Author

Brent L. Nannenga

Subjects

Inorganic Chemistry, Crystallography, Materials science, Electron diffraction, Structural Biology, General Materials Science, Physical and Theoretical Chemistry, Condensed Matter Physics, Biochemistry

Published

2019

13. MicroED opens a new era for biological structure determination

Author

Brent L. Nannenga and Tamir Gonen

Subjects

0301 basic medicine, Physics, Diffraction, Cryoelectron Microscopy, Proteins, Nanotechnology, Electrons, Biological materials, Article, law.invention, 03 medical and health sciences, 030104 developmental biology, Imaging, Three-Dimensional, Electron diffraction, Structural Biology, Atomic resolution, law, Biological structure, Microscopy, Humans, Electron microscope, Molecular Biology

Abstract

In 2013 we unveiled the cryo-electron microscopy (CryoEM) method of MicroED, or three-dimensional (3D) electron diffraction of microscopic crystals. Here tiny 3D crystals of biological material are used in an electron microscope for diffraction data collection under cryogenic conditions. The data is indexed, integrated, merged and scaled using standard X-ray crystallography software to determine structures at atomic resolution. In this review we provide an overview of the MicroED method and compare it with other CryoEM methods.

Published

2016

14. Biomolecular structure determination by electron diffraction of 3D microcrystals

Author

Brent L. Nannenga

Subjects

Inorganic Chemistry, Crystallography, Materials science, Electron diffraction, Structural Biology, General Materials Science, Biomolecular structure, Physical and Theoretical Chemistry, Condensed Matter Physics, Biochemistry

Published

2018

15. Protein structure determination by MicroED

Author

Brent L. Nannenga and Tamir Gonen

Subjects

Protein structure, Electron diffraction, Structural Biology, Chemistry, Resolution (electron density), Cryoelectron Microscopy, Model protein, Analytic Sample Preparation Methods, Proteins, Nanotechnology, Crystallography, X-Ray, Molecular Biology, Article

Abstract

In this review we discuss the current advances relating to structure determination from protein microcrystals with special emphasis on the newly developed method called MicroED. This method uses a transmission electron cryo-microscope to collect electron diffraction data from extremely small 3-dimensional (3D) crystals. MicroED has been used to solve the 3D structure of the model protein lysozyme to 2.9 Å resolution. As the method further matures, MicroED promises to offer a unique and widely applicable approach to protein crystallography using nanocrystals.

Published

2014

16. Overview of Electron Crystallography of Membrane Proteins: Crystallization and Screening Strategies Using Negative Stain Electron Microscopy

Author

Matthew G. Iadanza, Tamir Gonen, Brent L. Nannenga, and Breanna S. Vollmar

Subjects

Crystallography, Electron crystallography, Chemistry, Cryo-electron microscopy, Cryoelectron Microscopy, Molecular Conformation, Membrane Proteins, General Medicine, Negative Staining, Biochemistry, Negative stain, Article, law.invention, Membrane protein, Structural Biology, law, Protein purification, Crystallization, Electron microscope, Lipid bilayer

Abstract

Electron cryomicroscopy, or cryoEM, is an emerging technique for studying the three-dimensional structures of proteins and large macromolecular machines. Electron crystallography is a branch of cryoEM in which structures of proteins can be studied at resolutions that rival those achieved by X-ray crystallography. Electron crystallography employs two-dimensional crystals of a membrane protein embedded within a lipid bilayer. The key to a successful electron crystallographic experiment is the crystallization, or reconstitution, of the protein of interest. This unit describes ways in which protein can be expressed, purified, and reconstituted into well-ordered two-dimensional crystals. A protocol is also provided for negative stain electron microscopy as a tool for screening crystallization trials. When large and well-ordered crystals are obtained, the structures of both protein and its surrounding membrane can be determined to atomic resolution.

Published

2013