Micro-crystal electron diffraction (MicroED) combines the efficiency of electron scattering with diffraction to allow structure determination from nano-sized crystalline samples in cryoelectron ...microscopy (cryo-EM). It has been used to solve structures of a diverse set of biomolecules and materials, in some cases to sub-atomic resolution. However, little is known about the damaging effects of the electron beam on samples during such measurements. We assess global and site-specific damage from electron radiation on nanocrystals of proteinase K and of a prion hepta-peptide and find that the dynamics of electron-induced damage follow well-established trends observed in X-ray crystallography. Metal ions are perturbed, disulfide bonds are broken, and acidic side chains are decarboxylated while the diffracted intensities decay exponentially with increasing exposure. A better understanding of radiation damage in MicroED improves our assessment and processing of all types of cryo-EM data.
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•Damage to the crystalline order is quantified in reciprocal space•Site-specific damage to sensitive moieties is assessed in real space•The effects of damage are particularly pronounced at resolutions better than 3 Å•At high resolution, damage is apparent at exposures as low as 1 e− Å−2
The scattered electrons in a cryo-EM measurement provide the information necessary to determine the atomic structure, but inevitably damage the sample. Radiation damage must be controlled to avoid compromising the result. Here, the relationship between exposure and damage is assessed in two different crystalline samples.
Self-templating assemblies of the human prion protein are clinically associated with transmissible spongiform encephalopathies. Here we present the cryo-EM structure of a denaturant- and ...protease-resistant fibril formed in vitro spontaneously by a 9.7-kDa unglycosylated fragment of the human prion protein. This human prion fibril contains two protofilaments intertwined with screw symmetry and linked by a tightly packed hydrophobic interface. Each protofilament consists of an extended beta arch formed by residues 106 to 145 of the prion protein, a hydrophobic and highly fibrillogenic disease-associated segment. Such structures of prion polymorphs serve as blueprints on which to evaluate the potential impact of sequence variants on prion disease.
Changes in lattice structure across sub-regions of protein crystals are challenging to assess when relying on whole crystal measurements. Because of this difficulty, macromolecular structure ...determination from protein micro and nanocrystals requires assumptions of bulk crystallinity and domain block substructure. Here we map lattice structure across micron size areas of cryogenically preserved three-dimensional peptide crystals using a nano-focused electron beam. This approach produces diffraction from as few as 1500 molecules in a crystal, is sensitive to crystal thickness and three-dimensional lattice orientation. Real-space maps reconstructed from unsupervised classification of diffraction patterns across a crystal reveal regions of crystal order/disorder and three-dimensional lattice tilts on the sub-100nm scale. The nanoscale lattice reorientation observed in the micron-sized peptide crystal lattices studied here provides a direct view of their plasticity. Knowledge of these features facilitates an improved understanding of peptide assemblies that could aid in the determination of structures from nano- and microcrystals by single or serial crystal electron diffraction.
Sequence variation in the β2α2 loop, residues 165-175 of the mammalian prion protein (PrP), influences its structure. To better understand the consequences of sequence variation in this region of the ...protein, we biochemically and biophysically interrogate natural and artificial sequence variants of the β2α2 loop of mammalian PrP. Using microcrystal electron diffraction (MicroED), we determine atomic resolution structures of segments encompassing residues 168-176 from the β2α2 loop of PrP with sequences corresponding to human, mouse/cow, bank vole/hamster, rabbit/pig/guinea pig, and naked mole rat (elk-T174S) β2α2 loops, as well as synthetic β2α2 loop sequences. This collection of structures presents two dominant amyloid packing polymorphisms. In the first polymorph, denoted "clasped", side chains within a sheet form polar clasps by facing each other
, exemplified by the mouse/cow, human, and bank vole/hamster sequences. Because its stability is derived from within a strand and through polar ladders within a sheet, the sequence requirements for the mating strand are less restrictive. A second polymorph, denoted "interdigitated," has sidechains interdigitate across mating sheets, exemplified by the elk, naked mole rat (elk T174S), and rabbit sequences. The two types of packing present distinct networks of stabilizing hydrogen bonds. The identity of residue 174 appears to strongly influence the packing adopted in these peptides, but consideration of the overall sequence of a given segment is needed to understand the stability of its assemblies. Incorporation of these β2α2 loop sequences into an 85 residue recombinant segment encoding wild-type bank vole PrP
demonstrates that even single residue substitutions could impact fibril morphology as evaluated by negative stain electron microscopy. This is in line with recent findings supporting the accessibility of different structural geometries by varied mammalian prion sequences, and indicates that sequence-specific polymorphisms may be influenced by residues in the β2α2 loop.
The cytosolic iron sulfur cluster assembly (CIA) scaffold biosynthesizes iron sulfur cluster cofactors for enzymes residing in the cytosol and the nucleus. In fungi and animals, it comprises two ...homologous ATPases, called Nbp35 and Cfd1 in yeast, which can form homodimeric and heterodimeric complexes. Both proteins are required for CIA function, but their individual roles are not well understood. Here we investigate the nucleotide affinity of each form of the scaffold for ATP and ADP to reveal any differences that could shed light on the functions of the different oligomeric forms of the protein or any distinct roles of the individual subunits. All forms of the CIA scaffold are specific for adenosine nucleotides and not guanosine nucleotides. Although the Cfd1 homodimer has no detectable ATPase activity, it binds ATP with an affinity comparable to that of the hydrolysis competent forms, Nbp352 and Nbp35-Cfd1. Titrations to determine the number of nucleotide binding sites combined with site-directed mutagenesis demonstrate that the nucleotide must bind to the Cfd1 subunit of the heterodimer before it can bind to Nbp35 and that the Cfd1 subunit is hydrolysis competent when bound to Nbp35 in the heterodimer. Altogether, our work reveals the distinct roles of the Nbp35 and Cfd1 subunits in their heterodimeric complex. Cfd1 controls nucleotide binding, and the Nbp35 subunit is required to activate nucleotide hydrolysis.
The cytosolic iron–sulfur cluster assembly (CIA) system assembles iron–sulfur (FeS) cluster cofactors and inserts them into >20 apoprotein targets residing in the cytosol and nucleus. Three CIA ...proteins, called Cia1, Cia2, and Met18 in yeast, form the targeting complex responsible for apo-target recognition. There is little information about the structure of this complex or its mechanism of CIA substrate recognition. Herein, we exploit affinity co-purification and size exclusion chromatography to determine the subunit connectivity and stoichiometry of the CIA targeting complex. We conclude that Cia2 is the organizing center of the targeting complex, which contains one Met18, two Cia1, and four Cia2 polypeptides. To probe target recognition specificity, we utilize the CIA substrates Leu1 and Rad3 as well as the Escherichia coli FeS-binding transcription factor FNR (fumerate nitrate reductase). We demonstrate that both of the yeast CIA substrates are recognized, whereas the bacterial protein is not. Thus, while the targeting complex exhibits flexible target recognition in vitro, it cannot promiscuously recognize any FeS protein. Additionally, we demonstrate that the full CIA targeting complex is required to stably bind Leu1 in vitro, whereas the Met18–Cia2 subcomplex is sufficient to recognize Rad3. Together, these results allow us to propose a unifying model for the architecture of this highly conserved complex and demonstrate what component or subcomplexes are vital for target identification.
The ice-nucleation protein InaZ from
contains a large number of degenerate repeats that span more than a quarter of its sequence and include the segment GSTSTA.
structures of this repeat segment, ...resolved to 1.1 Å by microfocus X-ray crystallography and to 0.9 Å by the cryo-EM method MicroED, were determined from both racemic and homochiral crystals. The benefits of racemic protein crystals for structure determination by MicroED were evaluated and it was confirmed that the phase restriction introduced by crystal centrosymmetry increases the number of successful trials during the
phasing of the electron diffraction data. Both homochiral and racemic GSTSTA form amyloid-like protofibrils with labile, corrugated antiparallel β-sheets that mate face to back. The racemic GSTSTA protofibril represents a new class of amyloid assembly in which all-left-handed sheets mate with their all-right-handed counterparts. This determination of racemic amyloid assemblies by MicroED reveals complex amyloid architectures and illustrates the racemic advantage in macromolecular crystallography, now with submicrometre-sized crystals.
The concept of ‘prion-like’ behavior has emerged in the study of diseases involving protein misfolding where fibrillar structures, called amyloids, self-propagate and induce disease in a fashion ...similar to prions. From a biological standpoint, in order to be considered ‘prion-like,’ a protein must traverse cells and tissues and further propagate via a templated conformational change. Since 2017, cryo-electron microscopy structures from patient-derived ‘prion-like’ amyloids, in particular tau, have been presented and revealed structural similarities shared across amyloids. Since 2021, cryo-EM structures from prions of known infectivity have been added to the ex vivo amyloid structure family. In this review, we discuss current proposals for the ‘prion-like’ mechanisms of spread for tau and prion protein as well as discuss different influencers on structures of aggregates from tauopathies and prion diseases. Lastly, we discuss some of the current hypotheses for what may distinguish structures that are ‘prion-like’ from transmissible prion structures.
•Prion-like aggregates exit, are taken up, and propagate across cells and tissues.•Tau fibril structures point to isoform-composition-based structural patterns.•Prion strains share structural similarities despite host prion sequence variation.•GSS harbors a distinct structure to those of scrapie-derived prion strains.•A structural line between prion and prion-like may be thin.
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Iron sulfur cluster biosynthesis is essential in all organisms, but there are currently few cell‐based assays to monitor the cluster assembly and transfer process
in vivo
. Here we ...describe our work toward development of a genetically encoded Fe
4
S
4
cluster sensor that could be used to probe cluster dynamics
in vivo
. Our sensor design utilizes the cluster driven dimerization of the
E. coli
transcription factor Fumarate and Nitrate Reductase (FNR) to provide a FRET based readout of cluster binding levels. A fluorescent FNR was developed via genetic fusion of a SNAP‐tag to FNR's C terminus. The SNAP‐tag can be covalently labeled with a variety of fluorophores. We have purified the FNR‐SNAP fusion, verified it can be labeled with fluorophores, and determined that the fusion is monomeric in the absence of 4Fe4S
2+
cluster. With a cluster stabilizing mutant we have demonstrated that the fusion is capable of binding cluster. However, after fluorescent labeling of a mutant known to induce dimerization in the absence of cluster with fluorophores capable of a FRET interaction we were unable to detect a measurable FRET signal. Further analysis of the dimerization mutant implied that the SNAP tag in its current position interferes with the efficiency of dimerization. Current work is focused on minimizing the distance between labels via deletion of FNR's DNA binding domain.
Support or Funding Information
Boston University UROP
We use computational design coupled with experimental characterization to systematically investigate the design principles for macrocycle membrane permeability and oral bioavailability. We designed ...184 6–12 residue macrocycles with a wide range of predicted structures containing noncanonical backbone modifications and experimentally determined structures of 35; 29 are very close to the computational models. With such control, we show that membrane permeability can be systematically achieved by ensuring all amide (NH) groups are engaged in internal hydrogen bonding interactions. 84 designs over the 6–12 residue size range cross membranes with an apparent permeability greater than 1 × 10−6 cm/s. Designs with exposed NH groups can be made membrane permeable through the design of an alternative isoenergetic fully hydrogen-bonded state favored in the lipid membrane. The ability to robustly design membrane-permeable and orally bioavailable peptides with high structural accuracy should contribute to the next generation of designed macrocycle therapeutics.
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•Computational design of diverse permeable macrocycles beyond the “rule-of-five” space•X-ray and NMR structures of designed macrocycles match their computational models•Designed macrocycles are permeable in vitro and orally bioavailable in vivo•Designed chameleonic peptides show solvent-dependent conformational switching
An investigation of the design principles of macrocyclic peptide membrane permeability and oral bioavailability enables the generation of synthetic macrocycles that fold into the predicted conformation, can cross membranes, and even adopt different conformations depending on polar versus nonpolar contexts.
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