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Cryo-transmission electron microscopy reveals the initiation of glucose isomerase crystals and their growth into different crystalline or gel polymorphs, and shows that mutating specific amino acids controls which polymorph grows. Watching the birth of a crystal Mike Sleutel and colleagues performed cryo-transmission electron microscopy to investigate the birth, or nucleation, of protein crystals and their growth into two different crystalline structures and one disordered gel state. The two crystal polymorphs displayed unique nucleation pathways with their own building blocks for nucleus formation. The prismatic polymorph and the gel state shared the same fibrous precursor, and a fragment of the gel grew into new prismatic crystals. The authors analysed the intermolecular mode of binding and found that polymorphs could be selected by tuning the relative strengths of anisotropic versus isotropic attraction between the monomers. This enabled them to knock out specific polymorph growth via site-directed mutagenesis to tune the strength of attraction at specific contact sites. The authors hope that these insights could lead to new polymorph selection strategies of interest in medicine, structural biology and protein-based drug-delivery applications. The formation of condensed (compacted) protein phases is associated with a wide range of human disorders, such as eye cataracts 1 , amyotrophic lateral sclerosis 2 , sickle cell anaemia 3 and Alzheimer’s disease 4 . However, condensed protein phases have their uses: as crystals, they are harnessed by structural biologists to elucidate protein structures 5 , or are used as delivery vehicles for pharmaceutical applications 6 . The physiochemical properties of crystals can vary substantially between different forms or structures (‘polymorphs’) of the same macromolecule, and dictate their usability in a scientific or industrial context. To gain control over an emerging polymorph, one needs a molecular-level understanding of the pathways that lead to the various macroscopic states and of the mechanisms that govern pathway selection. However, it is still not clear how the embryonic seeds of a macromolecular phase are formed, or how these nuclei affect polymorph selection. Here we use time-resolved cryo-transmission electron microscopy to image the nucleation of crystals of the protein glucose isomerase, and to uncover at molecular resolution the nucleation pathways that lead to two crystalline states and one gelled state. We show that polymorph selection takes place at the earliest stages of structure formation and is based on specific building blocks for each space group. Moreover, we demonstrate control over the system by selectively forming desired polymorphs through site-directed mutagenesis, specifically tuning intermolecular bonding or gel seeding. Our results differ from the present picture of protein nucleation 7 , 8 , 9 , 10 , 11 , 12 , in that we do not identify a metastable dense liquid as the precursor to the crystalline state. Rather, we observe nucleation events that are driven by oriented attachments between subcritical clusters that already exhibit a degree of crystallinity. These insights suggest ways of controlling macromolecular phase transitions, aiding the development of protein-based drug-delivery systems and macromolecular crystallography.

Pyruvate carboxylase (PC) is a tetrameric enzyme that contains two active sites per subunit that catalyze two consecutive reactions. A mobile domain with an attached prosthetic biotin links both reactions, an initial biotin carboxylation and the subsequent carboxyl transfer to pyruvate substrate to produce oxaloacetate. Reaction sites are at long distance, and there are several co-factors that play as allosteric regulators. Here, using cryoEM we explore the structure of active PC tetramers focusing on active sites and on the conformational space of the oligomers. The results capture the mobile domain at both active sites and expose catalytic steps of both reactions at high resolution, allowing the identification of substrates and products. The analysis of catalytically active PC tetramers reveals the role of certain motions during enzyme functioning, and the structural changes in the presence of additional cofactors expose the mechanism for allosteric regulation. Pyruvate Carboxylase is a multifunctional enzyme that follows a multi-pathway reaction. Here, the authors, using cryoEM and classification techniques, reveal several catalytic states at reaction sites, the interplay between them, and their relationship with motions in the tetrameric organization.

The intrinsically disordered protein p15 PAF regulates DNA replication and repair by binding to the proliferating cell nuclear antigen (PCNA) sliding clamp. We present the structure of the human p15 PAF –PCNA complex. Crystallography and NMR show the central PCNA-interacting protein motif (PIP-box) of p15 PAF tightly bound to the front-face of PCNA. In contrast to other PCNA-interacting proteins, p15 PAF also contacts the inside of, and passes through, the PCNA ring. The disordered p15 PAF termini emerge at opposite faces of the ring, but remain protected from 20S proteasomal degradation. Both free and PCNA-bound p15 PAF binds DNA mainly through its histone-like N-terminal tail, while PCNA does not, and a model of the ternary complex with DNA inside the PCNA ring is consistent with electron micrographs. We propose that p15 PAF acts as a flexible drag that regulates PCNA sliding along the DNA and facilitates the switch from replicative to translesion synthesis polymerase binding. p15PAF regulates DNA replication and repair via interactions with the Proliferating Cell Nuclear Antigen (PCNA) sliding clamp. Here the authors present multi-faceted structural analyses of the p15-PCNA-DNA complex that suggests p15 regulates the sliding of PCNA along DNA during replication.

Macrophages mediate the elimination of pathogens by phagocytosis resulting in the activation of specific signaling pathways that lead to the production of cytokines, chemokines and other factors. Borrelia burgdorferi, the causative agent of Lyme disease, causes a wide variety of pro-inflammatory symptoms. The proinflammatory capacity of macrophages is intimately related to the internalization of the spirochete. However, most receptors mediating this process are largely unknown. We have applied a multiomic approach, including the proteomic analysis of B. burgdorferi-containing phagosome-enriched fractions, to identify surface receptors that are involved in the phagocytic capacity of macrophages as well as their inflammatory output. Sucrose gradient protein fractions of human monocyte-derived macrophages exposed to B. burgdorferi contained the phagocytic receptor, CR3/CD14 highlighting the major role played by these proteins in spirochetal phagocytosis. Other proteins identified in these fractions include C-type lectins, scavenger receptors or Siglecs, of which some are directly involved in the interaction with the spirochete. We also identified the Fc gamma receptor pathway, including the binding receptor, CD64, as involved both in the phagocytosis of, and TNF induction in response to B. burgdorferi in the absence of antibodies. The common gamma chain, FcγR, mediates the phagocytosis of the spirochete, likely through Fc receptors and C-type lectins, in a process that involves Syk activation. Overall, these findings highlight the complex array of receptors involved in the phagocytic response of macrophages to B. burgdorferi.

Turnip mosaic virus (TuMV), a potyvirus, is a flexible filamentous plant virus that displays a helical arrangement of coat protein copies (CPs) bound to the ssRNA genome. TuMV is a bona fide representative of the Potyvirus genus, one of most abundant groups of plant viruses, which displays a very wide host range. We have studied by cryoEM the structure of TuMV virions and its viral-like particles (VLPs) to explore the role of the interactions between proteins and RNA in the assembly of the virions. The results show that the CP-RNA interaction is needed for the correct orientation of the CP N-terminal arm, a region that plays as a molecular staple between CP subunits in the fully assembled virion.

The human cathelicidin LL-37 serves a critical role in the innate immune system defending bacterial infections. LL-37 can interact with molecules of the cell wall and perforate cytoplasmic membranes resulting in bacterial cell death. To test the interactions of LL-37 and bacterial cell wall components we crystallized LL-37 in the presence of detergents and obtained the structure of a narrow tetrameric channel with a strongly charged core. The formation of a tetramer was further studied by cross-linking in the presence of detergents and lipids. Using planar lipid membranes a small but defined conductivity of this channel could be demonstrated. Molecular dynamic simulations underline the stability of this channel in membranes and demonstrate pathways for the passage of water molecules. Time lapse studies of E. coli cells treated with LL-37 show membrane discontinuities in the outer membrane followed by cell wall damage and cell death. Collectively, our results open a venue to the understanding of a novel AMP killing mechanism and allows the rational design of LL-37 derivatives with enhanced bactericidal activity.

Antimicrobial peptides (AMPs) are ubiquitous weapons of all higher organisms to suppress antimicrobial growth. Despite intensive research, the killing mechanism of these peptides after interaction with the bacterial cell wall and cytoplasm is not well understood. To investigate this mechanism at a molecular level, we chose a well-studied AMP, Magainin-2 (Mag-2), for biophysical and structural studies. Circular dichroism experiments showed that the folding propensity of Mag-2 is strongly altered towards fully folded molecules in the presence of detergent. To study the pore-forming properties of Mag-2 in membranes, we crystallized the wild-type peptide in the presence of the membrane-mimicking dodecylphosphocholine detergent and obtained crystals diffracting to atomic resolution. Mag-2 structure shows an antiparallel arrangement of monomers, which is stabilised by a phenylalanine zipper motif spanning the hydrophobic interaction surface of this dimer. Trimerization of dimers leads to the formation of a hexameric peptide channel complex with a positively charged pore and a hydrophobic membrane-exposed belt. Using molecular dynamics simulations, a spontaneous flow of ions through this channel was observed, demonstrating anion-selectivity induced by the electrostatic potential characteristics of Mag-2. This first atomic-resolution structure of wild-type Mag-2 showing oligomerization will allow the rational design of improved Mag-2 peptide channels.

During synthesis of the ribosomal RNA precursor, RNA polymerase I (Pol I) monitors DNA integrity but its response to DNA damage remains poorly studied. Abasic sites are among the most prevalent DNA lesions in eukaryotic cells, and their detection is critical for cell survival. We report cryo-EM structures of Pol I in different stages of stalling at abasic sites, supported by in vitro transcription studies. Slow nucleotide addition opposite abasic sites occurs through base sandwiching between the RNA 3′-end and the Pol I bridge helix. Templating abasic sites can also cause Pol I cleft opening, which enables the A12 subunit to access the active center. Nucleotide addition opposite the lesion induces a translocation intermediate where DNA bases tilt to form hydrogen bonds with the new RNA base. These findings reveal unique mechanisms of Pol I stalling at abasic sites, differing from arrest by bulky lesions or abasic site handling by RNA polymerase II. Upon encounter of abasic lesions, a highly-prevalent DNA damage, RNA polymerase I experiences a two-step pausing-stalling mechanism that is described here through cryo-EM analysis. The structures uncover the nucleotide entry mechanism and provide insights into intrinsic RNA cleavage.

The R2TP/Prefoldin-like co-chaperone, in concert with HSP90, facilitates assembly and cellular stability of RNA polymerase II, and complexes of PI3-kinase-like kinases such as mTOR. However, the mechanism by which this occurs is poorly understood. Here we use cryo-EM and biochemical studies on the human R2TP core (RUVBL1–RUVBL2–RPAP3–PIH1D1) which reveal the distinctive role of RPAP3, distinguishing metazoan R2TP from the smaller yeast equivalent. RPAP3 spans both faces of a single RUVBL ring, providing an extended scaffold that recruits clients and provides a flexible tether for HSP90. A 3.6 Å cryo-EM structure reveals direct interaction of a C-terminal domain of RPAP3 and the ATPase domain of RUVBL2, necessary for human R2TP assembly but absent from yeast. The mobile TPR domains of RPAP3 map to the opposite face of the ring, associating with PIH1D1, which mediates client protein recruitment. Thus, RPAP3 provides a flexible platform for bringing HSP90 into proximity with diverse client proteins. The R2TP/PFDL co-chaperone facilitates assembly of RNA polymerase II and PI3-kinase-like kinases such as mTOR by a so far unknown mechanism. Here authors provide the cryo-EM structure of human R2TP, which shows how RPAP3 serves as a flexible platform to recruit HSP90 to diverse client proteins.

Antimicrobial peptides as part of the mammalian innate immune system target and remove major bacterial pathogens, often through irreversible damage of their cellular membranes. To explore the mechanism by which the important cathelicidin peptide LL-37 of the human innate immune system interacts with membranes, we performed biochemical, biophysical and structural studies. The crystal structure of LL-37 displays dimers of anti-parallel helices and the formation of amphipathic surfaces. Peptide-detergent interactions introduce remodeling of this structure after occupation of defined hydrophobic sites at the dimer interface. Furthermore, hydrophobic nests are shaped between dimer structures providing another scaffold enclosing detergents. Both scaffolds underline the potential of LL-37 to form defined peptide-lipid complexes in vivo . After adopting the activated peptide conformation LL-37 can polymerize and selectively extract bacterial lipids whereby the membrane is destabilized. The supramolecular fibril-like architectures formed in crystals can be reproduced in a peptide-lipid system after nanogold-labelled LL-37 interacted with lipid vesicles as followed by electron microscopy. We suggest that these supramolecular structures represent the LL-37-membrane active state. Collectively, our study provides new insights into the fascinating plasticity of LL-37 demonstrated at atomic resolution and opens the venue for LL-37-based molecules as novel antibiotics.