Two‐domain analysis of JmjN‐JmjC and PHD‐JmjC lysine demethylases: Detecting an inter‐domain evolutionary stress

Residues at different positions of a multiple sequence alignment sometimes evolve together, due to a correlated structural or functional stress at these positions. Co‐evolution has thus been evidenced computationally in multiple proteins or protein domains. Here, we wish to study whether an evolutionary stress is exerted on a sequence alignment across protein domains, i.e., on longer sequence separations than within a single protein domain. JmjC‐containing lysine demethylases were chosen for analysis, as a follow‐up to previous studies; these proteins are important multidomain epigenetic regulators. In these proteins, the JmjC domain is responsible for the demethylase activity, and surrounding domains interact with histones, DNA or partner proteins. This family of enzymes was analyzed at the sequence level, in order to determine whether the sequence of JmjC‐domains was affected by the presence of a neighboring JmjN domain or PHD finger in the protein. Multiple positions within JmjC sequences were shown to have their residue distributions significantly altered by the presence of the second domain. Structural considerations confirmed the relevance of the analysis for JmjN‐JmjC proteins, while among PHD‐JmjC proteins, the length of the linker region could be correlated to the residues observed at the most affected positions. The correlation of domain architecture with residue types at certain positions, as well as that of overall architecture with protein function, is discussed. The present results thus evidence the existence of an across‐domain evolutionary stress in JmjC‐containing demethylases, and provide further insights into the overall domain architecture of JmjC domain‐containing proteins.     

N‐terminal lysines are essential for protein translocation via a modified ERAD system in complex plastids

Nuclear‐encoded pre‐proteins being imported into complex plastids of red algal origin have to cross up to five membranes. Thereby, transport across the second outermost or periplastidal membrane (PPM) is facilitated by SELMA (symbiont‐specific ERAD‐like machinery), an endoplasmic reticulum‐associated degradation (ERAD)‐derived machinery. Core components of SELMA are enzymes involved in ubiquitination (E1 – E3), a Cdc48 ATPase complex and Derlin proteins. These components are present in all investigated organisms with four membrane‐bound complex plastids of red algal origin, suggesting a ubiquitin‐dependent translocation process of substrates mechanistically similar to the process of retro‐translocation in ERAD. Even if, according to the current model, translocation via SELMA does not end up in the classical poly‐ubiquitination, transient mono‐/oligo‐ubiquitination of pre‐proteins might be required for the mechanism of translocation. We investigated the import mechanism of SELMA and were able to show that protein transport across the PPM depends on lysines in the N‐terminal but not in the C‐terminal part of pre‐proteins. These lysines are predicted to be targets of ubiquitination during the translocation process. As proteins lacking the N‐terminal lysines get stuck in the PPM, a ‘frozen intermediate’ of the translocation process could be envisioned and initially characterized.     

The divergence and positive selection of the plant‐specific BURP‐containing protein family

BURP domain‐containing proteins belong to a plant‐specific protein family and have diverse roles in plant development and stress responses. However, our understanding about the genetic divergence patterns and evolutionary rates of these proteins remain inadequate. In this study, 15 plant genomes were explored to elucidate the genetic origins, divergence, and functions of these proteins. One hundred and twenty‐five BURP protein‐encoding genes were identified from four main plant lineages, including 13 higher plant species. The absence of BURP family genes in unicellular and multicellular algae suggests that this family (1) appeared when plants shifted from relatively stable aquatic environments to land, where conditions are more variable and stressful, and (2) is critical in the adaptation of plants to adverse environments. Promoter analysis revealed that several responsive elements to plant hormones and external environment stresses are concentrated in the promoter region of BURP protein‐encoding genes. This finding confirms that these genes influence plant stress responses. Several segmentally and tandem‐duplicated gene pairs were identified from eight plant species. Thus, in general, BURP domain‐containing genes have been subject to strong positive selection, even though these genes have conformed to different expansion models in different species. Our study also detected certain critical amino acid sites that may have contributed to functional divergence among groups or subgroups. Unexpectedly, all of the critical amino acid residues of functional divergence and positive selection were exclusively located in the C‐terminal region of the BURP domain. In conclusion, our results contribute novel insights into the genetic divergence patterns and evolutionary rates of BURP proteins.     

JMJD5 cleaves monomethylated histone H3 N‐tail under DNA damaging stress

The histone H3 N‐terminal protein domain (N‐tail) is regulated by multiple posttranslational modifications, including methylation, acetylation, phosphorylation, and by proteolytic cleavage. However, the mechanism underlying H3 N‐tail proteolytic cleavage is largely elusive. Here, we report that JMJD5, a Jumonji C (JmjC) domain‐containing protein, is a Cathepsin L‐type protease that mediates histone H3 N‐tail proteolytic cleavage under stress conditions that cause a DNA damage response. JMJD5 clips the H3 N‐tail at the carboxyl side of monomethyl‐lysine (Kme1) residues. In vitro H3 peptide digestion reveals that JMJD5 exclusively cleaves Kme1 H3 peptides, while little or no cleavage effect of JMJD5 on dimethyl‐lysine (Kme2), trimethyl‐lysine (Kme3), or unmethyl‐lysine (Kme0) H3 peptides is observed. Although H3 Kme1 peptides of K4, K9, K27, and K36 can all be cleaved by JMJD5 in vitro, K9 of H3 is the major cleavage site in vivo, and H3.3 is the major H3 target of JMJD5 cleavage. Cleavage is enhanced at gene promoters bound and repressed by JMJD5 suggesting a role for H3 N‐tail cleavage in gene expression regulation.     

Fine‐tuning sortase‐mediated immobilization of protein layers on surfaces using sequential deprotection and coupling

Increasing interest in protein immobilization on surfaces has heightened the need for techniques enabling layer‐by‐layer protein attachment. Here, we report a technique for controlling enzyme‐mediated immobilization of layers of protein on the surface using a genetically encoded protecting group. An enterokinase‐cleavable peptide sequence was inserted at the N‐terminus of bifunctional fluorescent proteins containing Sortase A substrate recognition tags at both ends to control Sortase A‐mediated protein immobilization on the surface layer‐by‐layer. Efficient, sequential immobilization of a second layer of protein using Sortase A required removal of the N‐terminal protecting group, suggesting the method enables multilayer synthesis using cyclic deprotection and coupling steps. © 2017 American Institute of Chemical Engineers Biotechnol. Prog., 33:824–831, 2017     

Crystal structure of the UBR‐box from UBR6/FBXO11 reveals domain swapping mediated by zinc binding

The UBR‐box is a 70‐residue zinc finger domain present in the UBR family of E3 ubiquitin ligases that directly binds N‐terminal degradation signals in substrate proteins. UBR6, also called FBXO11, is an UBR‐box containing E3 ubiquitin ligase that does not bind N‐terminal signals. Here, we present the crystal structure of the UBR‐box domain from human UBR6. The dimeric crystal structure reveals a unique form of domain swapping mediated by zinc coordination, where three independent protein chains come together to regenerate the topology of the monomeric UBR‐box fold. Analysis of the structure suggests that the absence of N‐terminal residue binding arises from the lack of an amino acid binding pocket.     

N‐Terminal methylation of proteasome subunit Rpt1 in yeast

The 26S proteasome is a multicatalytic protease complex that degrades ubiquitinated proteins in eukaryotic cells. It consists of a proteolytic core (the 20S proteasome) as well as regulatory particles, which contain six ATPase (Rpt) subunits involved in unfolding and translocation of substrates to the catalytic chamber of the 20S proteasome. In this study, we used MS to analyze the N‐terminal modifications of the yeast Rpt1 subunit, which contains the N‐terminal recognition sequence for N‐methyltransferase. Our results revealed that following the removal of the initiation Met residue of yeast Rpt1, the N‐terminal Pro residue is either unmodified, mono‐methylated, or di‐methylated, and that this N‐methylation has not been conserved throughout evolution. In order to gain a better understanding of the possible function(s) of the Pro‐Lys (PK) sequence at positions 3 and 4 of yeast Rpt1, we generated mutant strains expressing an Rpt1 allele that lacks this sequence. The absence of the PK sequence abolished N‐methylation, decreased cell growth, and increased sensitivity to stress. Our data suggest that N‐methylation of Rpt1 and/or its PK sequence might be important in cell growth or stress tolerance in yeast.     

Cooperative DNA‐binding and sequence‐recognition mechanism of aristaless and clawless

To achieve accurate gene regulation, some homeodomain proteins bind cooperatively to DNA to increase those site specificities. We report a ternary complex structure containing two homeodomain proteins, aristaless (Al) and clawless (Cll), bound to DNA. Our results show that the extended conserved sequences of the Cll homeodomain are indispensable to cooperative DNA binding. In the Al–Cll–DNA complex structure, the residues in the extended regions are used not only for the intermolecular contacts between the two homeodomain proteins but also for the sequence‐recognition mechanism of DNA by direct interactions. The residues in the extended N‐terminal arm lie within the minor groove of DNA to form direct interactions with bases, whereas the extended conserved region of the C‐terminus of the homeodomain interacts with Al to stabilize and localize the third α helix of the Cll homeodomain. This structure suggests a novel mode for the cooperativity of homeodomain proteins.     

The bacterial N‐end rule pathway: expect the unexpected

The N‐end rule pathway is a highly conserved process that operates in many different organisms. It relates the metabolic stability of a protein to its N‐terminal amino acid. Consequently, amino acids are described as either ‘stabilizing’ or ‘destabilizing’. Destabilizing residues are organized into three hierarchical levels: primary, secondary, and in eukaryotes – tertiary. Secondary and tertiary destabilizing residues act as signals for the post‐translational modification of the target protein, ultimately resulting in the attachment of a primary destabilizing residue to the N‐terminus of the protein. Regardless of their origin, proteins containing N‐terminal primary destabilizing residues are recognized by a key component of the pathway. In prokaryotes, the recognition component is a specialized adaptor protein, known as ClpS, which delivers target proteins directly to the ClpAP protease for degradation. In contrast, eukaryotes use a family of E3 ligases, known as UBRs, to recognize and ubiquitylate their substrates resulting in their turnover by the 26S proteasome. While the physiological role of the N‐end rule pathway is largely understood in eukaryotes, progress on the bacterial pathway has been slow. However, new interest in this area of research has invigorated several recent advances, unlocking some of the secrets of this unique proteolytic pathway in prokaryotes.     

Chaperone‐client interactions between Hsp21 and client proteins monitored in solution by small angle X‐ray scattering and captured by crosslinking mass spectrometry

The small heat shock protein (sHsp) chaperones are important for stress survival, yet the molecular details of how they interact with client proteins are not understood. All sHsps share a folded middle domain to which is appended flexible N‐ and C‐terminal regions varying in length and sequence between different sHsps which, in different ways for different sHsps, mediate recognition of client proteins. In plants there is a chloroplast‐localized sHsp, Hsp21, and a structural model suggests that Hsp21 has a dodecameric arrangement with six N‐terminal arms located on the outside of the dodecamer and six inwardly‐facing. Here, we investigated the interactions between Hsp21 and thermosensitive model substrate client proteins in solution, by small‐angle X‐ray scattering (SAXS) and crosslinking mass spectrometry. The chaperone‐client complexes were monitored and the R_g‐values were found to increase continuously during 20 min at 45°, which could reflect binding of partially unfolded clients to the flexible N‐terminal arms of the Hsp21 dodecamer. No such increase in R_g‐values was observed with a mutational variant of Hsp21, which is mainly dimeric and has reduced chaperone activity. Crosslinking data suggest that the chaperone‐client interactions involve the N‐terminal region in Hsp21 and only certain parts in the client proteins. These parts are peripheral structural elements presumably the first to unfold under destabilizing conditions. We propose that the flexible and hydrophobic N‐terminal arms of Hsp21 can trap and refold early‐unfolding intermediates with or without dodecamer dissociation.     

Self‐association of TPR domains: Lessons learned from a designed,consensus‐based TPR oligomer

The tetratricopeptide repeat (TPR) motif is a protein–protein interaction module that acts as an organizing centre for complexes regulating a multitude of biological processes. Despite accumulating evidence for the formation of TPR oligomers as an additional level of regulation there is a lack of structural and solution data explaining TPR self‐association. In the present work we characterize the trimeric TPR‐containing protein YbgF, which is linked to the Tol system in Gram‐negative bacteria. By subtracting previously identified TPR consensus residues required for stability of the fold from residues conserved across YbgF homologs, we identified residues involved in oligomerization of the C‐terminal YbgF TPR domain. Crafting these residues, which are located in loop regions between TPR motifs, onto the monomeric consensus TPR protein CTPR3 induced the formation of oligomers. The crystal structure of this engineered oligomer shows an asymmetric trimer where stacking interactions between the introduced tyrosines and displacement of the C‐terminal hydrophilic capping helix, present in most TPR domains, are key to oligomerization. Asymmetric trimerization of the YbgF TPR domain and CTPR3Y3 leads to the formation of higher order oligomers both in the crystal and in solution. However, such open‐ended self‐association does not occur in full‐length YbgF suggesting that the protein's N‐terminal coiled‐coil domain restricts further oligomerization. This interpretation is borne out in experiments where the coiled‐coil domain of YbgF was engineered onto the N‐terminus of CTPR3Y3 and shown to block self‐association beyond trimerization. Our study lays the foundations for understanding the structural basis for TPR domain self‐association and how such self‐association can be regulated in TPR domain‐containing proteins. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Characterization of CNPY5 and its family members

The Canopy (CNPY) family consists of four members predicted to be soluble proteins localized to the endoplasmic reticulum (ER). They are involved in a wide array of processes, including angiogenesis, cell adhesion, and host defense. CNPYs are thought to do so via regulation of secretory transport of a diverse group of proteins, such as immunoglobulin M, growth factor receptors, toll‐like receptors, and the low‐density lipoprotein receptor. Thus far, a comparative analysis of the mammalian CNPY family is missing. Bioinformatic analysis shows that mammalian CNPYs, except the CNPY1 homolog, have N‐terminal signal sequences and C‐terminal ER‐retention signals and that mammals have an additional member CNPY5, also known as plasma cell‐induced ER protein 1/marginal zone B cell‐specific protein 1. Canopy proteins are particularly homologous in four hydrophobic alpha‐helical regions and contain three conserved disulfide bonds. This sequence signature is characteristic for the saposin‐like superfamily and strongly argues that CNPYs share this common saposin fold. We showed that CNPY2, 3, 4, and 5 (termed CNPYs) localize to the ER. In radioactive pulse‐chase experiments, we found that CNPYs rapidly form disulfide bonds and fold within minutes into their native forms. Disulfide bonds in native CNPYs remain sensitive to low concentrations of dithiothreitol (DTT) suggesting that the cysteine residues forming them are relatively accessible to solutes. Possible roles of CNPYs in the folding of secretory proteins in the ER are discussed.     

The C‐terminal portion of the cleaved HT motif is necessary and sufficient to mediate export of proteins from the malaria parasite into its host cell

The malaria parasite exports proteins across its plasma membrane and a surrounding parasitophorous vacuole membrane, into its host erythrocyte. Most exported proteins contain a Host Targeting motif (HT motif) that targets them for export. In the parasite secretory pathway, the HT motif is cleaved by the protease plasmepsin V, but the role of the newly generated N‐terminal sequence in protein export is unclear. Using a model protein that is cleaved by an exogenous viral protease, we show that the new N‐terminal sequence, normally generated by plasmepsin V cleavage, is sufficient to target a protein for export, and that cleavage by plasmepsin V is not coupled directly to the transfer of a protein to the next component in the export pathway. Mutation of the fourth and fifth positions of the HT motif, as well as amino acids further downstream, block or affect the efficiency of protein export indicating that this region is necessary for efficient export. We also show that the fifth position of the HT motif is important for plasmepsin V cleavage. Our results indicate that plasmepsin V cleavage is required to generate a new N‐terminal sequence that is necessary and sufficient to mediate protein export by the malaria parasite.     

Sequence‐independent processing site of the C‐terminal domain (CTD) influences maturation of the RgpB protease from Porphyromonas gingivalis

The Gram‐negative periodontal pathogen Porphyromonas gingivalis produces a family of outer membrane‐anchored proteases, the gingipains, shown to play an essential role in virulence of the organism. The C‐terminal domain (CTD) of gingipains and other secreted proteins is known to be the targeting signal for maturation and translocation of the protein through the outer membrane. The CTD is subsequently cleaved during the secretion process. Multiple alignment of various CTDs failed to define a consensus sequence at the putative CTD processing site. Using mutagenesis, we were able to show that cleavage at the site is not dependent on a specific residue and that recognition of the site is independent of local sequence. Interestingly, length of the junction between the CTD and adjacent Ig‐like subdomain has a critical influence on post‐translational glycan modification of the protein, whereby insertion of additional residues immediately N‐terminal to the cleavage site results in failure of glycan modification and release of soluble protease into the culture medium. Various hypotheses are presented to explain these phenomena. Knowledge of the role CTDs play in maturation of gingipains has broader application for understanding maturation of CTD homologues expressed by bacteria of the Bacteriodetes phylum.     

Two different CC‐NBS‐LRR genes are required for Lr10‐mediated leaf rust resistance in tetraploid and hexaploid wheat

Comparative study of disease resistance genes in crop plants and their relatives provides insight on resistance gene function, evolution and diversity. Here, we studied the allelic diversity of the Lr10 leaf rust resistance gene, a CC‐NBS‐LRR coding gene originally isolated from hexaploid wheat, in 20 diploid and tetraploid wheat lines. Besides a gene in the tetraploid wheat variety ‘Altar’ that is identical to the hexaploid wheat Lr10, two additional, functional resistance alleles showing sequence diversity were identified by virus‐induced gene silencing in tetraploid wheat lines. In contrast to most described NBS‐LRR proteins, the N‐terminal CC domain of LR10 was found to be under strong diversifying selection. A second NBS‐LRR gene at the Lr10 locus, RGA2, was shown through silencing to be essential for Lr10 function. Interestingly, RGA2 showed much less sequence diversity than Lr10. These data demonstrate allelic diversity of functional genes at the Lr10 locus in tetraploid wheat, and these new genes can now be analyzed for agronomic relevance. Lr10‐based resistance is highly unusual both in its dependence on two, only distantly, related CC‐NBS‐LRR proteins, as well as in the pattern of diversifying selection in the N‐terminal domain. This indicates a new and complex molecular mechanism of pathogen detection and signal transduction.     

Generation of branched actin networks: assembly and regulation of the N‐WASP and WAVE molecular machines

The Arp2/3 complex is a molecular machine that generates branched actin networks responsible for membrane remodeling during cell migration, endocytosis, and other morphogenetic events. This machine requires activators, which themselves are multiprotein complexes. This review focuses on recent advances concerning the assembly of stable complexes containing the most‐studied activators, N‐WASP and WAVE proteins, and the level of regulation that is provided by these complexes. N‐WASP is the paradigmatic auto‐inhibited protein, which is activated by a conformational opening. Even though this regulation has been successfully reconstituted in vitro with isolated N‐WASP, the native dimeric complex with a WIP family protein has unique additional properties. WAVE proteins are part of a pentameric complex, whose basal state and activated state when bound to the Rac GTPase were recently clarified. Moreover, this review attempts to put together diverse observations concerning the WAVE complex in the conceptual frame of an in vivo assembly pathway that has gained support from the recent identification of a precursor.