The C‐degron pathway eliminates mislocalized proteins and products of deubiquitinating enzymes

Protein termini are determinants of protein stability. Proteins bearing degradation signals, or degrons, at their amino‐ or carboxyl‐termini are eliminated by the N‐ or C‐degron pathways, respectively. We aimed to elucidate the function of C‐degron pathways and to unveil how normal proteomes are exempt from C‐degron pathway‐mediated destruction. Our data reveal that C‐degron pathways remove mislocalized cellular proteins and cleavage products of deubiquitinating enzymes. Furthermore, the C‐degron and N‐degron pathways cooperate in protein removal. Proteome analysis revealed a shortfall in normal proteins targeted by C‐degron pathways, but not of defective proteins, suggesting proteolysis‐based immunity as a constraint for protein evolution/selection. Our work highlights the importance of protein termini for protein quality surveillance, and the relationship between the functional proteome and protein degradation pathways.     

TSGIT: An N‐ and C‐terminal tandem tag system for purification of native and intein‐mediated ligation‐ready proteins

A large variety of fusion tags have been developed to improve protein expression, solubilization, and purification. Nevertheless, these tags have been combined in a rather limited number of composite tags and usually these composite tags have been dictated by traditional commercially‐available expression vectors. Moreover, most commercially‐available expression vectors include either N‐ or C‐terminal fusion tags but not both. Here, we introduce TSGIT, a fusion‐tag system composed of both N‐ and a C‐terminal composite fusion tags. The system includes two affinity tags, two solubilization tags and two cleavable tags distributed at both termini of the protein of interest. Therefore, the N‐ and the C‐terminal composite fusion tags in TSGIT are fully orthogonal in terms of both affinity selection and cleavage. For using TSGIT, we streamlined the cloning, expression, and purification procedures. Each component tag is selected to maximize its benefits toward the final construct. By expressing and partially purifying the protein of interest between the components of the TSGIT fusion, the full‐length protein is selected over truncated forms, which has been a long‐standing problem in protein purification. Moreover, due to the nature of the cleavable tags in TSGIT, the protein of interest is obtained in its native form without any additional undesired N‐ or C‐terminal amino acids. Finally, the resulting purified protein is ready for efficient ligation with other proteins or peptides for downstream applications. We demonstrate the use of this system by purifying a large amount of native fluorescent mRuby3 protein and bacteriophage T7 gp2.5 ssDNA‐binding protein.     

Cryo‐EM reveals mechanisms of angiotensin I‐converting enzyme allostery and dimerization

Hypertension (high blood pressure) is a major risk factor for cardiovascular disease, which is the leading cause of death worldwide. The somatic isoform of angiotensin I‐converting enzyme (sACE) plays a critical role in blood pressure regulation, and ACE inhibitors are thus widely used to treat hypertension and cardiovascular disease. Our current understanding of sACE structure, dynamics, function, and inhibition has been limited because truncated, minimally glycosylated forms of sACE are typically used for X‐ray crystallography and molecular dynamics simulations. Here, we report the first cryo‐EM structures of full‐length, glycosylated, soluble sACE (sACE^S1211). Both monomeric and dimeric forms of the highly flexible apo enzyme were reconstructed from a single dataset. The N‐ and C‐terminal domains of monomeric sACE^S1211 were resolved at 3.7 and 4.1 Å, respectively, while the interacting N‐terminal domains responsible for dimer formation were resolved at 3.8 Å. Mechanisms are proposed for intradomain hinging, cooperativity, and homodimerization. Furthermore, the observation that both domains were in the open conformation has implications for the design of sACE modulators.     

Phospho‐regulation,nucleotide binding and ion access control in potassium‐chloride cotransporters

Potassium‐coupled chloride transporters (KCCs) play crucial roles in regulating cell volume and intracellular chloride concentration. They are characteristically inhibited under isotonic conditions via phospho‐regulatory sites located within the cytoplasmic termini. Decreased inhibitory phosphorylation in response to hypotonic cell swelling stimulates transport activity, and dysfunction of this regulatory process has been associated with various human diseases. Here, we present cryo‐EM structures of human KCC3b and KCC1, revealing structural determinants for phospho‐regulation in both N‐ and C‐termini. We show that phospho‐mimetic KCC3b is arrested in an inward‐facing state in which intracellular ion access is blocked by extensive contacts with the N‐terminus. In another mutant with increased isotonic transport activity, KCC1Δ19, this interdomain interaction is absent, likely due to a unique phospho‐regulatory site in the KCC1 N‐terminus. Furthermore, we map additional phosphorylation sites as well as a previously unknown ATP/ADP‐binding pocket in the large C‐terminal domain and show enhanced thermal stabilization of other CCCs by adenine nucleotides. These findings provide fundamentally new insights into the complex regulation of KCCs and may unlock innovative strategies for drug development.     

Isotope‐labeled amyloid‐β does not transmit to the brain in a prion‐like manner after peripheral administration

Findings of early cerebral amyloid‐β deposition in mice after peripheral injection of amyloid‐β‐containing brain extracts, and in humans following cadaveric human growth hormone treatment raised concerns that amyloid‐β aggregates and possibly Alzheimer’s disease may be transmissible between individuals. Yet, proof that Aβ actually reaches the brain from the peripheral injection site is lacking. Here, we use a proteomic approach combining stable isotope labeling of mammals and targeted mass spectrometry. Specifically, we generate ¹³C‐isotope‐labeled brain extracts from mice expressing human amyloid‐β and track ¹³C‐lysine‐labeled amyloid‐β after intraperitoneal administration into young amyloid precursor protein‐transgenic mice. We detect injected amyloid‐β in the liver and lymphoid tissues for up to 100 days. In contrast, injected ¹³C‐lysine‐labeled amyloid‐β is not detectable in the brain whereas the mice incorporate ¹³C‐lysine from the donor brain extracts into endogenous amyloid‐β. Using a highly sensitive and specific proteomic approach, we demonstrate that amyloid‐β does not reach the brain from the periphery. Our study argues against potential transmissibility of Alzheimer’s disease while opening new avenues to uncover mechanisms of pathophysiological protein deposition.     

SARS‐CoV‐2 nucleocapsid protein phase‐separates with RNA and with human hnRNPs

Tightly packed complexes of nucleocapsid protein and genomic RNA form the core of viruses and assemble within viral factories, dynamic compartments formed within the host cells associated with human stress granules. Here, we test the possibility that the multivalent RNA‐binding nucleocapsid protein (N) from severe acute respiratory syndrome coronavirus 2 (SARS‐CoV‐2) condenses with RNA via liquid–liquid phase separation (LLPS) and that N protein can be recruited in phase‐separated forms of human RNA‐binding proteins associated with SG formation. Robust LLPS with RNA requires two intrinsically disordered regions (IDRs), the N‐terminal IDR and central‐linker IDR, as well as the folded C‐terminal oligomerization domain, while the folded N‐terminal domain and the C‐terminal IDR are not required. N protein phase separation is induced by addition of non‐specific RNA. In addition, N partitions in vitro into phase‐separated forms of full‐length human hnRNPs (TDP‐43, FUS, hnRNPA2) and their low‐complexity domains (LCs). These results provide a potential mechanism for the role of N in SARS‐CoV‐2 viral genome packing and in host‐protein co‐opting necessary for viral replication and infectivity.     

Determining folding and binding properties of the C‐terminal SH2 domain of SHP2

SH2 domains are a class of protein–protein interaction modules with the function to recognize and bind sequences characterized by the presence of a phosphorylated tyrosine. SHP2 is a protein phosphatase involved in the Ras‐ERK1/2 signaling pathway that possess two SH2 domains, namely, N‐SH2 and C‐SH2, that mediate the interaction of SHP2 with various partners and determine the regulation of its catalytic activity. One of the main interactors of the SH2 domains of SHP2 is Gab2, a scaffolding protein with critical role in determining cell differentiation. Despite their key biological role and the importance of a correct native fold to ensure it, the mechanism of binding of SH2 domains with their ligands and the determinants of their stability have been poorly characterized. In this article, we present a comprehensive kinetic study of the folding of the C‐SH2 domain and the binding mechanism with a peptide mimicking a region of Gab2. Our data, obtained at different pH and ionic strength conditions and supported by site‐directed mutagenesis, highlight the role of electrostatic interactions in the early events of recognition. Interestingly, our results suggest a key role of a highly conserved histidine residue among SH2 family in the interaction with negative charges carried by the phosphotyrosine of Gab2. Moreover, the analysis of the equilibrium and kinetic folding data of C‐SH2 describes a complex mechanism implying a change in rate‐limiting step at high denaturant concentrations. Our data are discussed under the light of previous works on N‐SH2 domain of SHP2 and other SH2 domains.     

Parkin drives pS65‐Ub turnover independently of canonical autophagy in Drosophila

Parkinson''s disease‐related proteins, PINK1 and Parkin, act in a common pathway to maintain mitochondrial quality control. While the PINK1‐Parkin pathway can promote autophagic mitochondrial turnover (mitophagy) following mitochondrial toxification in cell culture, alternative quality control pathways are suggested. To analyse the mechanisms by which the PINK1–Parkin pathway operates in vivo, we developed methods to detect Ser65‐phosphorylated ubiquitin (pS65‐Ub) in Drosophila. Exposure to the oxidant paraquat led to robust, Pink1‐dependent pS65‐Ub production, while pS65‐Ub accumulates in unstimulated parkin‐null flies, consistent with blocked degradation. Additionally, we show that pS65‐Ub specifically accumulates on disrupted mitochondria in vivo. Depletion of the core autophagy proteins Atg1, Atg5 and Atg8a did not cause pS65‐Ub accumulation to the same extent as loss of parkin, and overexpression of parkin promoted turnover of both basal and paraquat‐induced pS65‐Ub in an Atg5‐null background. Thus, we have established that pS65‐Ub immunodetection can be used to analyse Pink1‐Parkin function in vivo as an alternative to reporter constructs. Moreover, our findings suggest that the Pink1‐Parkin pathway can promote mitochondrial turnover independently of canonical autophagy in vivo.     

Controlled modulation of the dynamics of the Deinococcus grandis Dps N‐terminal tails by divalent metals

DNA‐binding proteins from starved cells (Dps) are small multifunctional nanocages expressed by prokaryotes in acute oxidative stress conditions or during the starvation‐induced stationary phase, as a bacterial defense mechanism. Dps proteins protect bacterial DNA from damage by either direct binding or by removing precursors of reactive oxygen species from solution. The DNA‐binding properties of most Dps proteins studied so far are related to their unordered, flexible, N‐ and C‐terminal extensions. In a previous work, we revealed that the N‐terminal tails of Deinoccocus grandis Dps shift from an extended to a compact conformation depending on the ionic strength of the buffer and detected a novel high‐spin ferrous iron center in the proximal ends of those tails. In this work, we further explore the conformational dynamics of the protein by probing the effect of divalent metals binding to the tail by comparing the metal‐binding properties of the wild‐type protein with a binding site‐impaired D34A variant using size exclusion chromatography, dynamic light scattering, synchrotron radiation circular dichroism, and small‐angle X‐ray scattering. The N‐terminal ferrous species was also characterized by Mössbauer spectroscopy. The results herein presented reveal that the conformation of the N‐terminal tails is altered upon metal binding in a gradual, reversible, and specific manner. These observations may point towards the existence of a regulatory process for the DNA‐binding properties of Dps proteins through metal binding to their N‐ and/or C‐terminal extensions.     

CTD of SARS‐CoV‐2 N protein is a cryptic domain for binding ATP and nucleic acid that interplay in modulating phase separation

SARS‐CoV‐2 nucleocapsid (N) protein plays essential roles in many steps of the viral life cycle, thus representing a key drug target. N protein contains the folded N‐/C‐terminal domains (NTD/CTD) and three intrinsically disordered regions, while its functions including liquid–liquid phase separation (LLPS) depend on the capacity in binding various viral/host‐cell RNA/DNA of diverse sequences. Previously NTD was established to bind various RNA/DNA while CTD to dimerize/oligomerize for forming high‐order structures. By NMR, here for the first time we decrypt that CTD is not only capable of binding S2m, a specific probe derived from SARS‐CoV‐2 gRNA but with the affinity even higher than that of NTD. Very unexpectedly, ATP, the universal energy currency for all living cells with high cellular concentrations (2–16 mM), specifically binds CTD with Kd of 1.49 ± 0.28 mM. Strikingly, the ATP‐binding residues of NTD/CTD are identical in the SARS‐CoV‐2 variants while ATP and S2m interplay in binding NTD/CTD, as well as in modulating LLPS critical for the viral life cycle. Results together not only define CTD as a novel binding domain for ATP and nucleic acid, but enforce our previous proposal that ATP has been evolutionarily exploited by SARS‐CoV‐2 to complete its life cycle in the host cell. Most importantly, the unique ATP‐binding pockets on NTD/CTD may offer promising targets for design of specific anti‐SARS‐CoV‐2 molecules to fight the pandemic. Fundamentally, ATP emerges to act at mM as a cellular factor to control the interface between the host cell and virus lacking the ability to generate ATP.     

TIMELESS‐TIPIN and UBXN‐3 promote replisome disassembly during DNA replication termination in Caenorhabditis elegans

The eukaryotic replisome is rapidly disassembled during DNA replication termination. In metazoa, the cullin‐RING ubiquitin ligase CUL‐2^LRR‐1 drives ubiquitylation of the CMG helicase, leading to replisome disassembly by the p97/CDC‐48 “unfoldase”. Here, we combine in vitro reconstitution with in vivo studies in Caenorhabditis elegans embryos, to show that the replisome‐associated TIMELESS‐TIPIN complex is required for CUL‐2^LRR‐1 recruitment and efficient CMG helicase ubiquitylation. Aided by TIMELESS‐TIPIN, CUL‐2^LRR‐1 directs a suite of ubiquitylation enzymes to ubiquitylate the MCM‐7 subunit of CMG. Subsequently, the UBXN‐3 adaptor protein directly stimulates the disassembly of ubiquitylated CMG by CDC‐48_UFD‐1_NPL‐4. We show that UBXN‐3 is important in vivo for replisome disassembly in the absence of TIMELESS‐TIPIN. Correspondingly, co‐depletion of UBXN‐3 and TIMELESS causes profound synthetic lethality. Since the human orthologue of UBXN‐3, FAF1, is a candidate tumour suppressor, these findings suggest that manipulation of CMG disassembly might be applicable to future strategies for treating human cancer.     

Solution X‐ray scattering highlights discrepancies in Plasmodium multi‐aminoacyl‐tRNA synthetase complexes

tRip is a tRNA import protein specific to Plasmodium, the causative agent of malaria. In addition to its membrane localization and tRNA trafficking properties, tRip has the capacity to associate with three aminoacyl‐tRNA synthetases (aaRS), the glutamyl‐ (ERS), glutaminyl‐ (QRS), and methionyl‐ (MRS) tRNA synthetases. In eukaryotes, such multi‐aaRSs complexes (MSC) regulate the moonlighting activities of aaRSs. In Plasmodium, tRip and the three aaRSs all contain an N‐terminal GST‐like domain involved in the assembly of two independent complexes: the Q‐complex (tRip:ERS:QRS) and the M‐complex (tRip:ERS:MRS) with a 2:2:2 stoichiometry and in which the association of the GST‐like domains of tRip and ERS (tRip‐N:ERS‐N) is central. In this study, the crystal structure of the N‐terminal GST‐like domain of ERS was solved and made possible further investigation of the solution architecture of the Q‐ and M‐complexes by small‐angle x‐ray scattering (SAXS). This strategy relied on the engineering of a tRip‐N‐ERS‐N chimeric protein to study the structural scaffold of both Plasmodium MSCs and confirm the unique homodimerization pattern of tRip in solution. The biological impact of these structural arrangements is discussed.     

N‐terminal acetylation modestly enhances phase separation and reduces aggregation of the low‐complexity domain of RNA‐binding protein fused in sarcoma

The RNA‐binding protein fused in sarcoma (FUS) assembles via liquid–liquid phase separation (LLPS) into functional RNA granules and aggregates in amyotrophic lateral sclerosis associated neuronal inclusions. Several studies have demonstrated that posttranslational modification (PTM) can significantly alter FUS phase separation and aggregation, particularly charge‐altering phosphorylation of the nearly uncharged N‐terminal low complexity domain of FUS (FUS LC). However, the occurrence and impact of N‐terminal acetylation on FUS phase separation remains unexplored, even though N‐terminal acetylation is the most common PTM in mammals and changes the charge at the N‐terminus. First, we find that FUS is predominantly acetylated in two human cell types and stress conditions. Next, we show that recombinant FUS LC can be acetylated when co‐expressed with the NatA complex in Escherichia coli. Using NMR spectroscopy, we find that N‐terminal acetylated FUS LC (FUS LC Nt‐Ac) does not notably alter monomeric FUS LC structure or motions. Despite no difference in structure, Nt‐Ac‐FUS LC phase separates more avidly than unmodified FUS LC. More importantly, N‐terminal acetylation of FUS LC reduces aggregation. Our findings highlight the importance of N‐terminal acetylation of proteins that undergo physiological LLPS and pathological aggregation.     

NLRP3 activation contributes to endothelin‐1‐induced erectile dysfunction

In the present study, we hypothesized that endothelin (ET) receptors (ET_A and ET_B) stimulation, through increased calcium and ROS formation, leads to Nucleotide Oligomerization Domain‐Like Receptor Family, Pyrin Domain Containing 3 (NLRP3) activation. Intracavernosal pressure (ICP/MAP) was measured in C57BL/6 (WT) mice. Functional and immunoblotting assays were performed in corpora cavernosa (CC) strips from WT, NLRP3^−/− and caspase^−/− mice in the presence of ET‐1 (100 nM) and vehicle, MCC950, tiron, BAPTA AM, BQ123, or BQ788. ET‐1 reduced the ICP/MAP in WT mice, and MCC950 prevented the ET‐1 effect. ET‐1 decreased CC ACh‐, sodium nitroprusside (SNP)‐induced relaxation, and increased caspase‐1 expression. BQ123 an ET_A receptor antagonist reversed the effect. The ET_B receptor antagonist BQ788 also reversed ET‐1 inhibition of ACh and SNP relaxation. Additionally, tiron, BAPTA AM, and NLRP3 genetic deletion prevented the ET‐1‐induced loss of ACh and SNP relaxation. Moreover, BQ123 diminished CC caspase‐1 expression, while BQ788 increased caspase‐1 and IL‐1β levels in a concentration‐dependent manner (100 nM–10 μM). Furthermore, tiron and BAPTA AM prevented ET‐1‐induced increase in caspase‐1. In addition, BAPTA AM blocked ET‐1‐induced ROS generation. In conclusion, ET‐1‐induced erectile dysfunction depends on ET_A‐ and ET_B‐mediated activation of NLRP3 in mouse CC via Ca²⁺‐dependent ROS generation.     

AvrRps4 effector family processing and recognition in lettuce

During pathogenesis, effector proteins are secreted from the pathogen to the host plant to provide virulence activity for invasion of the host. However, once the host plant recognizes one of the delivered effectors, effector‐triggered immunity activates a robust immune and hypersensitive response (HR). In planta, the effector AvrRps4 is processed into the N‐terminus (AvrRps4^N) and the C‐terminus (AvrRps4^C). AvrRps4^C is sufficient to trigger HR in turnip and activate AtRRS1/AtRPS4‐mediated immunity in Arabidopsis; on the other hand, AvrRps4^N induces HR in lettuce. Furthermore, AvrRps4^N‐mediated HR requires a conserved arginine at position 112 (R112), which is also important for full‐length AvrRps4 (AvrRps4^F) processing. Here, we show that effector processing and effector recognition in lettuce are uncoupled for the AvrRps4 family. In addition, we compared effector recognition by lettuce of AvrRps4 and its homologues, HopK1 and XopO. Interestingly, unlike for AvrRps4 and HopK1, mutation of the conserved R111 in XopO by itself was insufficient to abolish recognition. The combination of amino acid substitutions arginine 111 to leucine with glutamate 114 to lysine abolished the XopO‐mediated HR, suggesting that AvrRps4 family members have distinct structural requirements for perception by lettuce. Together, our results provide an insight into the processing and recognition of AvrRps4 and its homologues.     

Cryo‐EM structure of the octameric pore of Clostridium perfringens β‐toxin

Clostridium perfringens is one of the most widely distributed and successful pathogens producing an impressive arsenal of toxins. One of the most potent toxins produced is the C. perfringens β‐toxin (CPB). This toxin is the main virulence factor of type C strains. We describe the cryo‐electron microscopy (EM) structure of CPB oligomer. We show that CPB forms homo‐octameric pores like the hetero‐oligomeric pores of the bi‐component leukocidins, with important differences in the receptor binding region and the N‐terminal latch domain. Intriguingly, the octameric CPB pore complex contains a second 16‐stranded β‐barrel protrusion atop of the cap domain that is formed by the N‐termini of the eight protomers. We propose that CPB, together with the newly identified Epx toxins, is a member a new subclass of the hemolysin‐like family. In addition, we show that the β‐barrel protrusion domain can be modified without affecting the pore‐forming ability, thus making the pore particularly attractive for macromolecule sensing and nanotechnology. The cryo‐EM structure of the octameric pore of CPB will facilitate future developments in both nanotechnology and basic research.