Identification of an endocytosis motif in an intracellular loop of Wntless protein, essential for its recycling and the control of Wnt protein signaling

The secretion of Wnt signaling proteins is dependent upon the transmembrane sorting receptor, Wntless (Wls), which recycles between the trans-Golgi network and the cell surface. Loss of Wls results in impairment of Wnt secretion and defects in development and homeostasis in Drosophila, Caenorhabditis elegans, and the mouse. The sorting signals for the internalization and trafficking of Wls have not been defined. Here, we demonstrate that Wls internalization requires clathrin and dynamin I, components of the clathrin-mediated endocytosis pathway. Moreover, we have identified a conserved YXXφ endocytosis motif in the third intracellular loop of the multipass membrane protein Wls. Mutation of the tyrosine-based motif YEGL to AEGL (Y425A) resulted in the accumulation of human mutant Wls on the cell surface of transfected HeLa cells. The cell surface accumulation of Wls^AEGL was rescued by the insertion of a classical YXXφ motif in the cytoplasmic tail. Significantly, a Drosophila Wls^AEGL mutant displayed a wing notch phenotype, with reduced Wnt secretion and signaling. These findings demonstrate that YXXφ endocytosis motifs can occur in the intracellular loops of multipass membrane proteins and, moreover, provide direct evidence that the trafficking of Wls is required for efficient secretion of Wnt signaling proteins.     

Genetic Identification of Nascent Peptides That Induce Ribosome Stalling

Several nascent peptides stall ribosomes during their own translation in both prokaryotes and eukaryotes. Leader peptides that induce stalling can regulate downstream gene expression. Interestingly, stalling peptides show little sequence similarity and interact with the ribosome through distinct mechanisms. To explore the scope of regulation by stalling peptides and to better understand the mechanism of stalling, we identified and characterized new examples from random libraries. We created a genetic selection that ties the life of Escherichia coli cells to stalling at a specific site. This selection relies on the natural bacterial system that rescues arrested ribosomes. We altered transfer-messenger RNA, a key component of this rescue system, to direct the completion of a necessary protein if and only if stalling occurs. We identified three classes of stalling peptides: C-terminal Pro residues, SecM-like peptides, and the novel stalling sequence FXXYXIWPP. Like the leader peptides SecM and TnaC, the FXXYXIWPP peptide induces stalling efficiently by inhibiting peptidyl transfer. The nascent peptide exit tunnel and peptidyltransferase center are implicated in this stalling event, although mutations in the ribosome affect stalling on SecM and FXXYXIWPP differently. We conclude that ribosome stalling can be caused by numerous sequences and is more common than previously believed.     

Functional Specificity of CpG DNA-binding CXXC Domains in Mixed Lineage Leukemia

The MLL CXXC domain binds nonmethylated CpG-containing DNA and is essential for the oncogenic properties of MLL fusion proteins. To determine potential functional promiscuity of similar DNA binding domains, we replaced the MLL CXXC domain in the context of the leukemogenic MLL-AF9 fusion with CXXC domains from DNMT1, CGBP (CFP1), and MBD1, or with a methyl-CpG-binding domain (MBD) from MBD1. MLL(DNMT1 CXXC)-AF9 shows robust in vitro colony forming activity and in vivo leukemogenesis, similar to MLL-AF9. However, colony forming ability and leukemogenicity are abrogated in MLL-AF9 containing either the CGBP or MBD1 CXXC domains or the MBD1 MBD domain. Direct comparison of in vitro DNA binding affinity of the isolated CXXC or MBD domains demonstrated that MLL, DNMT1, and CGBP CXXC domains could each bind to unmethylated DNA but with differing affinity. In contrast, the isolated MBD1 CXXC and MBD1 MBD domains were unable to bind to the same DNA. However, all substituted domains still allowed targeting of the MLL fusions to the functionally important Hoxa9 locus in primary bone marrow progenitor cells. In addition to DNA binding activity, it was critical that specific CpG residues in the Hoxa9 locus were protected from methylation for leukemia development. This ultimately prevented histone 3 lysine 9 trimethylation (H3K9me3) of the locus and enabled Hoxa9 expression. These were properties shared by MLL and DNMT1 CXXC domains but not by CGBP CXXC or the other swapped fusions tested. We demonstrate that similar CXXC domains can be mechanistically distinguished by specificity of CpG nucleotides preferentially protected from DNA methylation.     

Identification of conserved secondary structures and expansion segments in enod40 RNAs reveals new enod40 homologues in plants

enod40 is a plant gene that participates in the regulation of symbiotic interaction between leguminous plants and bacteria or fungi. Furthermore, it has been suggested to play a general role in non-symbiotic plant development. Although enod40 seems to have multiple functions, being present in many land plants, the molecular mechanisms of its activity are unclear; they may be determined though, by short peptides and/or RNA structures encoded in the enod40 genes. We utilized conserved RNA structures in enod40 sequences to search nucleotide sequence databases and identified a number of new enod40 homologues in plant species that belong to known, but also, to yet unknown enod40-containing plant families. RNA secondary structure predictions and comparative sequence analysis of enod40 RNAs allowed us to determine the most conserved structural features, present in all known enod40 genes. Remarkably, the topology and evolution of one of the conserved structural domains are similar to those of the expansion segments found in structural RNAs such as rRNAs, RNase P and SRP RNAs. Surprisingly, the enod40 RNA structural elements are much more stronger conserved than the encoded peptides. This finding suggests that some general functions of enod40 gene could be determined by the encoded RNA structure, whereas short peptides may be responsible for more diverse functions found only in certain plant families.     

The salivary secretome of the tsetse fly Glossina pallidipes (Diptera: Glossinidae) infected by salivary gland hypertrophy virus

Background

The competence of the tsetse fly Glossina pallidipes (Diptera; Glossinidae) to acquire salivary gland hypertrophy virus (SGHV), to support virus replication and successfully transmit the virus depends on complex interactions between Glossina and SGHV macromolecules. Critical requisites to SGHV transmission are its replication and secretion of mature virions into the fly''s salivary gland (SG) lumen. However, secretion of host proteins is of equal importance for successful transmission and requires cataloging of G. pallidipes secretome proteins from hypertrophied and non-hypertrophied SGs.

Methodology/Principal Findings

After electrophoretic profiling and in-gel trypsin digestion, saliva proteins were analyzed by nano-LC-MS/MS. MaxQuant/Andromeda search of the MS data against the non-redundant (nr) GenBank database and a G. morsitans morsitans SG EST database, yielded a total of 521 hits, 31 of which were SGHV-encoded. On a false discovery rate limit of 1% and detection threshold of least 2 unique peptides per protein, the analysis resulted in 292 Glossina and 25 SGHV MS-supported proteins. When annotated by the Blast2GO suite, at least one gene ontology (GO) term could be assigned to 89.9% (285/317) of the detected proteins. Five (∼1.8%) Glossina and three (∼12%) SGHV proteins remained without a predicted function after blast searches against the nr database. Sixty-five of the 292 detected Glossina proteins contained an N-terminal signal/secretion peptide sequence. Eight of the SGHV proteins were predicted to be non-structural (NS), and fourteen are known structural (VP) proteins.

Conclusions/Significance

SGHV alters the protein expression pattern in Glossina. The G. pallidipes SG secretome encompasses a spectrum of proteins that may be required during the SGHV infection cycle. These detected proteins have putative interactions with at least 21 of the 25 SGHV-encoded proteins. Our findings opens venues for developing novel SGHV mitigation strategies to block SGHV infections in tsetse production facilities such as using SGHV-specific antibodies and phage display-selected gut epithelia-binding peptides.     

Insect antimicrobial peptides and their applications

Insects are one of the major sources of antimicrobial peptides/proteins (AMPs). Since observation of antimicrobial activity in the hemolymph of pupae from the giant silk moths Samia Cynthia and Hyalophora cecropia in 1974 and purification of first insect AMP (cecropin) from H. cecropia pupae in 1980, over 150 insect AMPs have been purified or identified. Most insect AMPs are small and cationic, and they show activities against bacteria and/or fungi, as well as some parasites and viruses. Insect AMPs can be classified into four families based on their structures or unique sequences: the α-helical peptides (cecropin and moricin), cysteine-rich peptides (insect defensin and drosomycin), proline-rich peptides (apidaecin, drosocin, and lebocin), and glycine-rich peptides/proteins (attacin and gloverin). Among insect AMPs, defensins, cecropins, proline-rich peptides, and attacins are common, while gloverins and moricins have been identified only in Lepidoptera. Most active AMPs are small peptides of 20–50 residues, which are generated from larger inactive precursor proteins or pro-proteins, but gloverins (~14 kDa) and attacins (~20 kDa) are large antimicrobial proteins. In this mini-review, we will discuss current knowledge and recent progress in several classes of insect AMPs, including insect defensins, cecropins, attacins, lebocins and other proline-rich peptides, gloverins, and moricins, with a focus on structural-functional relationships and their potential applications.     

Mechanism-based Proteomic Screening Identifies Targets of Thioredoxin-like Proteins

Thioredoxin (Trx)-fold proteins are protagonists of numerous cellular pathways that are subject to thiol-based redox control. The best characterized regulator of thiols in proteins is Trx1 itself, which together with thioredoxin reductase 1 (TR1) and peroxiredoxins (Prxs) comprises a key redox regulatory system in mammalian cells. However, there are numerous other Trx-like proteins, whose functions and redox interactors are unknown. It is also unclear if the principles of Trx1-based redox control apply to these proteins. Here, we employed a proteomic strategy to four Trx-like proteins containing CXXC motifs, namely Trx1, Rdx12, Trx-like protein 1 (Txnl1) and nucleoredoxin 1 (Nrx1), whose cellular targets were trapped in vivo using mutant Trx-like proteins, under conditions of low endogenous expression of these proteins. Prxs were detected as key redox targets of Trx1, but this approach also supported the detection of TR1, which is the Trx1 reductant, as well as mitochondrial intermembrane proteins AIF and Mia40. In addition, glutathione peroxidase 4 was found to be a Rdx12 redox target. In contrast, no redox targets of Txnl1 and Nrx1 could be detected, suggesting that their CXXC motifs do not engage in mixed disulfides with cellular proteins. For some Trx-like proteins, the method allowed distinguishing redox and non-redox interactions. Parallel, comparative analyses of multiple thiol oxidoreductases revealed differences in the functions of their CXXC motifs, providing important insights into thiol-based redox control of cellular processes.     

Regulation of Insulin Receptor Substrate 1 (IRS-1)/AKT Kinase-mediated Insulin Signaling by O-Linked ��-N-Acetylglucosamine in 3T3-L1 Adipocytes

Increased O-linked β-N-acetylglucosamine (O-GlcNAc) is associated with insulin resistance in muscle and adipocytes. Upon insulin treatment of insulin-responsive adipocytes, O-GlcNAcylation of several proteins is increased. Key insulin signaling proteins, including IRS-1, IRS-2, and PDK1, are substrates for OGT, suggesting potential O-GlcNAc control points within the pathway. To elucidate the roles of O-GlcNAc in dampening insulin signaling (Vosseller, K., Wells, L., Lane, M. D., and Hart, G. W. (2002) Proc. Natl. Acad. Sci. U. S. A. 99, 5313–5318), we focused on the pathway upstream of AKT. Increasing O-GlcNAc in 3T3-L1 adipocytes decreases phosphoinositide 3-kinase (PI3K) interactions with both IRS-1 and IRS-2. Elevated O-GlcNAc also reduces phosphorylation of the PI3K p85 binding motifs (YXXM) of IRS-1 and results in a concomitant reduction in tyrosine phosphorylation of Y⁶⁰⁸XXM in IRS-1, one of the two main PI3K p85 binding motifs. Additionally, insulin signaling stimulates the interaction of OGT with PDK1. We conclude that one of the steps at which O-GlcNAc contributes to insulin resistance is by inhibiting phosphorylation at the Y⁶⁰⁸XXM PI3K p85 binding motif in IRS-1 and possibly at PDK1 as well.     

Proteins in aggregates functionally impact multiple neurodegenerative disease models by forming proteasome‐blocking complexes

Age-dependent neurodegenerative diseases progressively form aggregates containing both shared components (e.g., TDP-43, phosphorylated tau) and proteins specific to each disease. We investigated whether diverse neuropathies might have additional aggregation-prone proteins in common, discoverable by proteomics. Caenorhabditis elegans expressing unc-54p/Q40::YFP, a model of polyglutamine array diseases such as Huntington''s, accrues aggregates in muscle 2–6 days posthatch. These foci, isolated on antibody-coupled magnetic beads, were characterized by high-resolution mass spectrometry. Three Q40::YFP-associated proteins were inferred to promote aggregation and cytotoxicity, traits reduced or delayed by their RNA interference knockdown. These RNAi treatments also retarded aggregation/cytotoxicity in Alzheimer''s disease models, nematodes with muscle or pan-neuronal Aβ_1–42 expression and behavioral phenotypes. The most abundant aggregated proteins are glutamine/asparagine-rich, favoring hydrophobic interactions with other random-coil domains. A particularly potent modulator of aggregation, CRAM-1/HYPK, contributed < 1% of protein aggregate peptides, yet its knockdown reduced Q40::YFP aggregates 72–86% (P < 10⁻⁶). In worms expressing Aβ_1–42, knockdown of cram-1 reduced β-amyloid 60% (P < 0.002) and slowed age-dependent paralysis > 30% (P < 10⁻⁶). In wild-type worms, cram-1 knockdown reduced aggregation and extended lifespan, but impaired early reproduction. Protection against seeded aggregates requires proteasome function, implying that normal CRAM-1 levels promote aggregation by interfering with proteasomal degradation of misfolded proteins. Molecular dynamic modeling predicts spontaneous and stable interactions of CRAM-1 (or human orthologs) with ubiquitin, and we verified that CRAM-1 reduces degradation of a tagged-ubiquitin reporter. We propose that CRAM-1 exemplifies a class of primitive chaperones that are initially protective and highly beneficial for early reproduction, but ultimately impair aggregate clearance and limit longevity.     

The Chaperones Hsp90 and Cdc37 Mediate the Maturation and Stabilization of Protein Kinase C through a Conserved PXXP Motif in the C-terminal Tail

The life cycle of protein kinase C (PKC) is tightly controlled by mechanisms that mature the enzyme, sustain the activation-competent enzyme, and degrade the enzyme. Here we show that a conserved PXXP motif (Kannan, N., Haste, N., Taylor, S. S., and Neuwald, A. F. (2007) Proc. Natl. Acad. Sci. U. S. A. 104, 1272–1277), in the C-terminal tail of AGC (c-AMP-dependent protein kinase/protein kinase G/protein kinase C) kinases, controls the processing phosphorylation of conventional and novel PKC isozymes, a required step in the maturation of the enzyme into a signaling-competent species. Mutation of both Pro-616 and Pro-619 to Ala in the conventional PKC βII abolishes the phosphorylation and activity of the kinase. Co-immunoprecipitation studies reveal that conventional and novel, but not atypical, PKC isozymes bind the chaperones Hsp90 and Cdc37 through a PXXP-dependent mechanism. Inhibitors of Hsp90 and Cdc37 significantly reduce the rate of processing phosphorylation of PKC. Of the two C-terminal sites processed by phosphorylation, the hydrophobic motif, but not the turn motif, is regulated by Hsp90. Overlay of purified Hsp90 onto a peptide array containing peptides covering the catalytic domain of PKC βII identified regions surrounding the PXXP segment, but not the PXXP motif itself, as major binding determinants for Hsp90. These Hsp90-binding regions, however, are tethered to the C-terminal tail via a “molecular clamp” formed between the PXXP motif and a conserved Tyr (Tyr-446) in the αE-helix. Disruption of the clamp by mutation of the Tyr to Ala recapitulates the phosphorylation defect of mutating the PXXP motif. These data are consistent with a model in which a molecular clamp created by the PXXP motif in the C-terminal tail and determinants in the αE-helix of the catalytic domain allows the chaperones Hsp90 and Cdc37 to bind newly synthesized PKC, a required event in the processing of PKC by phosphorylation.Protein kinases, which comprise ∼2% of the human genome, are key signal transducers that regulate a wide variety of cellular processes, such as growth, proliferation, and metabolism, through catalysis of specific phosphorylation events (1). By integrating signals from extracellular stimuli and transmitting them to targeted downstream substrates, protein kinases serve as a pivotal point of regulation within the cell. Deregulation and mutation of protein kinases play a causal role in human pathology, notably cancer, poising kinases as important targets for the design of therapeutics (2–5). Therefore, understanding the mechanisms that regulate protein kinases, such as those important for maturation and processing, would be critical for designing therapeutics that would maintain the correct functioning of signal transduction pathways.Heat shock proteins (Hsp),³ such as Hsp90, are ubiquitously expressed molecular chaperones that facilitate protein folding, regulate quality control, and guide protein turnover in an effort to maintain cellular homeostasis (6–8). Unlike other chaperones such as Hsp70, which non-specifically assists in folding of nascent polypeptide chains (7), Hsp90 works with a specific and discrete set of client proteins, particularly protein kinases (9). Many of the known client kinases of Hsp90, Src (10), Akt (11, 12), phosphoinositide dependent kinase-1 (PDK-1) (13), and ErbB2-/HER2 (14, 15), require the activity of Hsp90 to reach an activation-competent and mature state. Hsp90 is recruited to its kinase clients through interactions with cochaperones, such as Cdc37, which bridge the interaction between Hsp90 and the kinase client (16, 17); this mechanism is revealed in a structural analysis of the Cdc37-Cdk4-Hsp90 complex (18). Cdc37, originally identified in yeast (19), is a cochaperone specific to the kinome that not only assists Hsp90 function but can also recognize and stabilize clients independently of Hsp90 (20). By binding specific regions of the catalytic domains of these kinases, the Hsp90-Cdc37 complex utilizes ATP to promote and stabilize functional conformations of its clients (8, 16, 17, 21). Pharmacological inhibition of Hsp90 by ansamycin antibiotics such as 17-(allylamino)-17-demethoxygeldanamycin (17-AAG) leads to the destabilization and subsequent proteasomal degradation of its clients (6, 22). Recent studies have identified Hsp90 as a promising therapeutic target in cancer as levels of chaperones and activity of client kinases are frequently up-regulated (23–25).The protein kinase C (PKC) family of Ser/Thr kinases serves as a paradigm of how conformation and processing by phosphorylation regulate activity, localization, and inter- and intramolecular interactions (26). The mammalian PKC family consists of 10 isozymes divided into three subclasses (conventional, novel, and atypical) based on their primary structure and second messenger mode of regulation. In the case of conventional PKC isozymes, newly synthesized enzyme is loosely engaged on the membrane in a conformation that exposes the activation loop for phosphorylation by the upstream kinase, PDK-1 (28). This phosphorylation triggers two sequential phosphorylations on the C terminus, one on the turn motif and one on the hydrophobic motif. Phosphorylation of the turn motif is required for phosphorylation of the hydrophobic motif and has recently been shown to depend on the mammalian target of rapamycin complex 2 (mTORC2), a complex consisting of the mammalian target of rapamycin (mTOR), Rictor, Sin1, and mLST8 (29, 30). Turn motif phosphorylation is rapidly followed by phosphorylation at the hydrophobic motif, a reaction that occurs by an intramolecular mechanism in vitro (31). Fully stey phosphorylated PKC is released into the cytosol in a closed conformation in which an autoinhibitory pseudosubstrate sequence occupies the substrate-binding cavity. Upon generation of the lipid second messenger diacylglycerol and elevation of intracellular Ca²⁺, conventional PKC isozymes (α, βI, βII, γ) translocate to membranes via their membrane-targeting C1 and C2 domains, where they adopt an open conformation in which the pseudosubstrate is expelled from the substrate-binding cavity, permitting phosphorylation of downstream substrates (32). Novel PKC isozymes (δ, ε, θ, and η) only respond to diacylglycerol, and their processing phosphorylations can occur through additional mechanisms (33, 34). Atypical PKC isozymes (ζ and ι/λ) do not respond to either Ca²⁺ or diacylglycerol but can also undergo regulation of their processing phosphorylations by external stimuli (35). In fact, atypical PKC isozymes contain a Glu at their hydrophobic motif site. Thus, although these three sites are conserved among PKC family members, additional layers of regulation generate specificity in how these kinases become signaling-competent enzymes.The mechanisms of regulation of the activity and signaling properties of PKC by lipid second messengers and phosphorylation have been well characterized; however, mounting evidence suggests that there are many other regulatory inputs for PKC function. Recent analysis of the evolutionary constraints acting on AGC kinase sequences have underscored the importance of the C-terminal tail as a critical regulatory module (36). Deletion mutants of the C-terminal tail have been shown to abrogate PKC activity (37). In addition to containing the key regulatory phosphorylation sites and docking the upstream kinase PDK-1, the C-terminal tail contains key conserved motifs, found within all AGC kinases, that facilitate ATP binding, promote substrate binding, and structure the catalytic core (36). One such motif comprises the segment PXXP; this motif makes key contacts with the catalytic core, where it is important for modulating movement of the catalytic domain (36). Although this PXXP motif is conserved in all the PKC isozymes, its functional role is unknown.In this study, we address the role of the conserved Pro residues in the PXXP motif of the C-terminal tail of PKC βII. We show that mutation of these two Pro to Ala (P616A and P619A) results in a kinase that is not processed by phosphorylation in cells and is thus inactive. Further analysis reveals that this mutant is not able to bind the chaperones Hsp90 and Cdc37, an event that is required for the processing of PKC by phosphorylation. Our peptide array data indicate that Hsp90 binds to regions of the catalytic core such as the αC-β4 loop and the αD-helix that serve as hinge points for C-helix movement (36). Structural analysis delineates that these hinge points are tethered to the C-terminal tail through a molecular clamp formed between the PXXP segment and AGC conserved residues in the αE-helix. Mutation of one of the “clamping” residues, a conserved Tyr (Tyr-446), recapitulates the defect resulting from mutation of the PXXP motif. Our data support a model in which the PXXP motif participates in an intramolecular clamp with determinants in the αE helix of the kinase core, by providing a recognition surface for Hsp90 to bind and facilitate the maturation of PKC, a required step in the processing of the enzyme.     

Salt Bridge Swapping in the EXXERFXYY Motif of Proton-coupled Oligopeptide Transporters

Proton-coupled oligopeptide transporters (POTs) couple the inward transport of di- or tripeptides with an inwardly directed transport of protons. Evidence from several studies of different POTs has pointed toward involvement of a highly conserved sequence motif, E₁XXE₂RFXYY (from here on referred to as E₁XXE₂R), located on Helix I, in interactions with the proton. In this study, we investigated the intracellular substrate accumulation by motif variants with all possible combinations of glutamate residues changed to glutamine and arginine changed to a tyrosine, the latter being a natural variant found in the Escherichia coli POT YjdL. We found that YjdL motif variants with E₁XXE₂R, E₁XXE₂Y, E₁XXQ₂Y, or Q₁XXE₂Y were able to accumulate peptide, whereas those with E₁XXQ₂R, Q₁XXE₂R, or Q₁XXQ₂Y were unable to accumulate peptide, and Q₁XXQ₂R abolished uptake. These results suggest a mechanism that involves swapping of an intramotif salt bridge, i.e. R-E₂ to R-E₁, which is consistent with previous structural studies. Molecular dynamics simulations of the motif variants E₁XXE₂R and E₁XXQ₂R support this mechanism. The simulations showed that upon changing conformation arginine pushes Helix V, through interactions with the highly conserved FYING motif, further away from the central cavity in what could be a stabilization of an inward facing conformation. As E₂ has been suggested to be the primary site for protonation, these novel findings show how protonation may drive conformational changes through interactions of two highly conserved motifs.     

Autophagy and p62/sequestosome 1 generate neo-antimicrobial peptides (cryptides) from cytosolic proteins

In a manifestation of the immunological autophagy termed xenophagy, autophagic adapter proteins such as p62 and NDP52 directly capture microbes for delivery to autophagosomal organelles where they are eliminated. In a mirror image phenomenon, which is also an immunological variant of the process termed decryption, p62 and autophagy contribute to the elimination of Mycobacterium tuberculosis. During decryption, p62 sequesters cytosolic proteins into autophagosomes where they are proteolytically converted into peptides termed cryptides. A subset of cryptides possesses antimicrobial peptide properties exhibited upon their delivery to parasitophorous vacuoles where they kill intracellular microbes.Key words: autophagy, tuberculosis, ribosome, ubiquitin, antimicrobial peptidesAutophagy is an evolutionarily conserved cytoplasm-homeostatic process with a multitude of functions supporting, for the most part, cellular viability. During autophagy, cytoplasmic targets ranging from protein aggregates to whole organelles such as mitochondria and intracellular microbes are sequestered into a double-membrane bound organelle called the autophagosome. Autophagosomes mature into autolysosomes through fusion with lysosomes or their transport intermediates, bringing about acidification and acquisition of hydrolases leading to the digestion of the captured substrates. It is generally assumed that autophagy produces terminal degradative products such as free amino acids that are then used by the cell or the body as nutrients at times of starvation. Recently, we have discovered that autophagy generates, by proteolysis of captured cytosolic proteins, a mixture of peptides conferring potential cryptic biological functions, termed “cryptides.” Some of the cryptides with thus far assigned biological functions are the neo-antimicrobial peptides liberated from innocuous cytoplasmic proteins such as the ribosomal protein precursor FAU and ubiquitin.Our study was motivated by the search for factors or ingredients that make autophagic organelles particularly mycobactericidal, as Mycobacterium tuberculosis can survive the environment of the conventional phagolysosome. This was shown in the 1970s by the classical work of Armstrong and D''Arcy Hart at the same time when these authors established the more broadly appreciated and well-ingrained reputation of the tubercle bacillus as inhibiting the conventional phagosome-lysosome fusion. The approach to identifying such hypothetical ingredients was to first examine the steps of the autophagic pathway that are necessary for the mycobactericidal nature of macrophages induced for autophagy by, for example, starvation. We have found that not only are all stages of autophagy (initiation, elongation/closure and maturation) required for full mycobactericidal potency, but that p62, the first autophagic adapter characterized by the Johansen group, and also known as sequestosome 1, is absolutely required for autophagic elimination of M. tuberculosis. Sequestosome 1/p62 recognizes ubiquitinated protein aggregates and possibly ubiquitinated depolarized mitochondria and other targets, and delivers them to nascent autophagosomes; p62 also binds to the mammalian Atg8 paralog LC3 via its LC3-interaction region (LIR), thus conveniently bridging the targets with forming phagophores.At first blush, it may seem that mycobacteria follow the same fate demonstrated for several other bacteria, whereby p62 or another autophagic adapter, NDP52, capture cytosolic microbes and deliver them to autophagosomes. For example, the fraction of Salmonellae that are no longer retained within phagosomes and are free in the cytosol, or Shigella and Listeria that actively escape into the cytosol, are associated with ubiquitinated material or become otherwise recognized by p62 or NDP52, and end up being sequestered into autophagosomes. However, we found no evidence for p62 acting directly to transfer intraphagosomal mycobacteria into autophagic vacuoles. Instead, we observed p62-positive organelles as periodically fusing with mycobacterial phagosomes. At the same time, we found by imaging and biochemical means that proteins recruited by p62 from the cytosol into conventional autophagic organelles are subsequently transferred to model (latex bead phagosomes formed upon feeding 1 µm beads to macrophages) or mycobacterial phagosomes, as they gradually acquire autolysosomal characteristics. Next, we established that p62-captured cytosolic proteins (ribosomal protein rpS30 precursor FAU and ubiquitin) are proteolytically degraded into smaller peptides, and that specific peptides from these complex mixtures show antimycobacterial activity. Thus, the emerging model posits that autophagy captures cytosolic proteins and converts them into neo-antimycobacterial peptides that can then kill M. tuberculosis upon delivery to mycobacteria-containing phagosomes, which in turn gradually acquire autolysosomal properties (Fig. 1).Open in a separate windowFigure 1Elimination of M. tuberculosis by autophagy and p62. Mycobacteria are phagocytosed by macrophages and at least for some time reside within phagosomes. Upon induction of autophagy, p62, as a bifunctional agent interacting with autophagic substrates and with LC3, recruits into autophagosomes pre-antimicrobicidal cytosolic substrates. Autophagosome maturation including acquisition of lysosomal hydrolases leads to the proteolytic cleavage of p62 substrates and their conversion into peptides (cryptides) that can act as antimicrobial peptides.In contrast to the direct mechanism of capturing bacteria employed in some instances described above, in the case of M. tuberculosis, an organism that resides within the phagosomes, the adapter molecule p62 exerts its anti-microbial action through an indirect, but rather sophisticated mechanism. By sequestering into autophagosomes the initially harmless cytosolic components and by proteolytically processing them within maturing autophagosomes, p62 and autophagy liberate antimicrobial peptides from the otherwise innocuous substrates. This amounts to a resourceful utilization by the cell of otherwise spent or to-be-discarded cytoplasmic proteins and gives them an after-function upon completion of their “day jobs” that they performed as whole proteins.Our studies have uncovered a previously unappreciated function for autophagy in generating neo-antimicrobial peptides, and perhaps also opened the prospect for other biological functions potentially engendered by the products of autophagic proteolysis. Given that autophagy has the capacity to capture en masse and subject to digestion large sections of the cytoplasm, most cellular proteins are undergoing, or can undergo, processing into peptides or peptide intermediates within autophagic organelles. We postulate that the antimicrobial peptide production revealed in our studies thus far is only one manifestation of a spectrum of potential biological functions of cryptides generated by autophagy.     

Critical Role of Flanking Residues in NGR-to-isoDGR Transition and CD13/Integrin Receptor Switching

Various NGR-containing peptides have been exploited for targeted delivery of drugs to CD13-positive tumor neovasculature. Recent studies have shown that compounds containing this motif can rapidly deamidate and generate isoaspartate-glycine-arginine (isoDGR), a ligand of αvβ3-integrin that can be also exploited for drug delivery to tumors. We have investigated the role of NGR and isoDGR peptide scaffolds on their biochemical and biological properties. Peptides containing the cyclic CNGRC sequence could bind CD13-positive endothelial cells more efficiently than those containing linear GNGRG. Peptide degradation studies showed that cyclic peptides mostly undergo NGR-to-isoDGR transition and CD13/integrin switching, whereas linear peptides mainly undergo degradation reactions involving the α-amino group, which generate non-functional six/seven-membered ring compounds, unable to bind αvβ3, and small amount of isoDGR. Structure-activity studies showed that cyclic isoDGR could bind αvβ3 with an affinity >100-fold higher than that of linear isoDGR and inhibited endothelial cell adhesion and tumor growth more efficiently. Cyclic isoDGR could also bind other integrins (αvβ5, αvβ6, αvβ8, and α5β1), although with 10–100-fold lower affinity. Peptide linearization caused loss of affinity for all integrins and loss of specificity, whereas α-amino group acetylation increased the affinity for all tested integrins, but caused loss of specificity. These results highlight the critical role of molecular scaffold on the biological properties of NGR/isoDGR peptides. These findings may have important implications for the design and development of anticancer drugs or tumor neovasculature-imaging compounds, and for the potential function of different NGR/isoDGR sites in natural proteins.     

Deciphering Structural and Functional Roles of Individual Disulfide Bonds of the Mitochondrial Sulfhydryl Oxidase Erv1p

Erv1p is a FAD-dependent sulfhydryl oxidase of the mitochondrial intermembrane space. It contains three conserved disulfide bonds arranged in two CXXC motifs and one CX₁₆C motif. Experimental evidence for the specific roles of the individual disulfide bonds is lacking. In this study, structural and functional roles of the disulfides were dissected systematically using a wide range of biochemical and biophysical methods. Three double cysteine mutants with each pair of cysteines mutated to serines were generated. All of the mutants were purified with the normal FAD binding properties as the wild type Erv1p, showing that none of the three disulfides are essential for FAD binding. Thermal denaturation and trypsin digestion studies showed that the CX₁₆C disulfide plays an important role in stabilizing the folding of Erv1p. To understand the functional role of each disulfide, small molecules and the physiological substrate protein Mia40 were used as electron donors in oxygen consumption assays. We show that both CXXC disulfides are required for Erv1 oxidase activity. The active site disulfide is well protected thus requires the shuttle disulfide for its function. Although both mutants of the CXXC motifs were individually inactive, Erv1p activity was partially recovered by mixing these two mutants together, and the recovery was rapid. Thus, we provided the first experimental evidence of electron transfer between the shuttle and active site disulfides of Erv1p, and we propose that both intersubunit and intermolecular electron transfer can occur.Disulfide bonds play very important roles in the structure and function of many proteins by stabilizing protein folding and/or acting as thiol/disulfide redox switches. The process of disulfide formation is catalyzed by dedicated enzymes in vivo (1–4). Erv1p is a FAD-dependent sulfhydryl oxidase located in the Saccharomyces cerevisiae mitochondrial intermembrane space (4–6). It is an essential component of the redox regulated Mia40/Erv1 import and assembly pathway used by many of the cysteine-containing intermembrane space proteins, such as members of the “small Tim” and Cox17 families (7–10). Upon import of a Cys-reduced substrate, Mia40 interacts with the substrate via intermolecular disulfide bond and shuttles a disulfide to its substrate. Although oxidized Mia40 promotes disulfide bond formation in the substrates, Erv1p functions in catalyzing reoxidation of the reduced Mia40 and/or release of the substrate (11–13).The common features for the FAD-dependent sulfhydryl oxidases are that the enzymes can catalyze the electron transfer from substrate molecules (e.g. protein thiols) through the noncovalent bound FAD cofactor to molecular oxygen or oxidized cytochrome c (14). The sulfhydryl oxidases can be divided into three groups: Ero1 enzymes, multidomain quiesin sulfhydryl oxidases, and single domain Erv (essential for respiration and vegetative growth)/ALR proteins. The yeast Ero1p and the mammalian homologues (Ero1α and Ero1β) are large flavoenzymes present in the ER with at least five disulfide bonds, but only two of the disulfide bonds are conserved. The conserved cysteines are essential for the catalytic activity of Ero1p forming the active site CXXC and shuttle disulfide CX₄C, respectively (15, 16). Furthermore, nonconserved disulfide bonds have been shown recently to be important in regulating the activity of both yeast and mammalian Ero1 (17–19). The second group of oxidases, the multidomain quiesin sulfhydryl oxidases, have important functions in higher eukaryotes (14, 20). Quiesin sulfhydryl oxidases consist of an Erv/ALR module fused to one or more thioredoxin-like domains with two conserved CXXC motifs in the Erv/ALR module. Quiesin sulfhydryl oxidase enzymes are found in many subcellular and extracellular locations, but not in mitochondria. Instead, single domain Erv/ARL enzymes of the third group are found in the 7mitochondria of many eukaryotic cells (21). Erv1p belongs to this single domain Erv/ARL family, which includes the human mitochondrial ARL, plant AtErv1, and yeast Erv2p of the ER lumen.The Erv/ARL enzymes are characterized by a highly conserved central catalytic core of ∼100 amino acids, which includes an active site CXXC motif (Cys¹³⁰–Cys¹³³ for Erv1p), CX₁₆C disulfide bond (Cys¹⁵⁹–Cys¹⁷⁶ for Erv1p), and residues involved in FAD binding (Fig. 1A). Based on the partial crystal structure data of Erv2p (22) and AtErv1 (23), the catalytic core of Erv proteins contains a four-helix bundle forming the noncovalent FAD-binding site with the active site CXXC in close proximity to the isoalloxazine ring of FAD. In addition, the long range CX₁₆C disulfide bond of the Erv proteins brings the short fifth helix to the four-helix bundle in proximity to the adenine ring of FAD (Fig. 1A). Thus, the CX₁₆C disulfide bond is proposed to play a structural role in stabilizing the FAD binding and/or protein folding, but direct experimental evidence to verify the roles is lacking. Apart from the catalytic core, the other parts of the proteins seem flexible and unfolded. Importantly, all members of the Erv/ALR family have at least an additional disulfide bond located in the nonconserved N- or C-terminal region to the catalytic core (Fig. 1B), which is hypothesized as a shuttle disulfide based on the partial crystal structure of Erv2 (22). The hypothesized shuttle disulfide of Erv2p CXC and AtErv1 CX₄C are located in the C terminus, but Erv1p (Cys³⁰–Cys³³) and ALR have a CXXC shuttle disulfide located N-terminal to the catalytic core. Furthermore, structural and chemical data have suggested that Erv/ARL enzymes form homodimer or oligomers in the presence or absence of intermolecular disulfide bonds (5, 23, 24).Open in a separate windowFIGURE 1.Structure and conserved Cys motifs of Erv/ALR enzymes. A, modeled structures of the conserved central catalytic core domain of Erv1p dimer based on the crystal structure data of AtErv1 (Protein Data Bank accession number 2HJ3, residues 73–173, the helix 1 starts with residue 75). The helices of the four-helix bundle and the short fifth helix are labeled from 1 to 5. The two disulfides are shown as yellow spheres, and the cofactor FAD is in red. The Cys¹³⁰–Cys¹³³ is the redox active disulfide located closely to the isoalloxazine ring of FAD. The N and C termini were labeled as N and C, respectively. The structure was generated using Pymol program. B, schematic of the primary structure of yeast, plant, and human sulfhydryl oxidase with the conserved Cys motifs. The conserved central catalytic core regions are shown as black bars, and the nonconserved regions are in gray.Yeast mitochondrial Erv1p contains a total of six Cys residues forming three pairs of disulfide bonds (residues 30–33, 130–133, and 159–176) as described above. Previous studies with single Cys mutants showed that although all three disulfide bonds are essential for Erv1p function in vivo, only Cys¹³⁰–Cys¹³³ disulfide is required for the oxidase activity of Erv1p in vitro (24). The conclusion that only Cys¹³⁰–Cys¹³³ disulfide is required for Erv1p oxidase activity in vitro was based on a study using the artificial substrate DTT² as the electron donor. Abnormal color changes were observed for some of the single Cys mutants of Erv1p in the previous study that were probably caused by protein misfolding or formation of non-native disulfides because of the presence of a redox active but unpaired Cys. It is clear that Cys¹³⁰–Cys¹³³ is the active site disulfide; however, experimental evidence for the role of Cys³⁰–Cys³³ disulfide is lacking, and the specific role played by the unique CX₁₆C motif of Erv proteins is unknown.In this study, we dissected the structural and functional roles of all three individual disulfides of Erv1p systematically. To avoid misfolding via unpaired Cys, three double Cys mutants of Erv1p were generated with each of the disulfides mutated to serines. All three mutants were successfully purified with the normal FAD binding properties of the wild type (WT) Erv1p. Various biophysical and biochemical methods were used to study the folding and oxidase activity of the WT and Erv1p mutants. Both artificial and the natural substrate (Mia40) of Erv1p were used as electron donors to understand the functional mechanism of Erv1p. Our results show that both the first (Cys³⁰–Cys³³) and second (Cys¹³⁰–Cys¹³³) disulfides are essential for Erv1 oxidase activity in vitro. Although none of the three disulfides are essential for FAD binding, the third disulfide (Cys¹⁵⁹–Cys¹⁷⁶) plays an important role in stabilizing the folding of Erv1p. More importantly, this study provided direct experimental evidence to show that Cys³⁰–Cys³³ functionally acts as a shuttle disulfide passing electrons to the active site Cys¹³⁰–Cys¹³³ disulfide. Moreover, the electron transfer seems to occur through both intersubunit and intermolecular interactions.     

Structural and sequence analysis of imelysin-like proteins implicated in bacterial iron uptake

Imelysin-like proteins define a superfamily of bacterial proteins that are likely involved in iron uptake. Members of this superfamily were previously thought to be peptidases and were included in the MEROPS family M75. We determined the first crystal structures of two remotely related, imelysin-like proteins. The Psychrobacter arcticus structure was determined at 2.15 Å resolution and contains the canonical imelysin fold, while higher resolution structures from the gut bacteria Bacteroides ovatus, in two crystal forms (at 1.25 Å and 1.44 Å resolution), have a circularly permuted topology. Both structures are highly similar to each other despite low sequence similarity and circular permutation. The all-helical structure can be divided into two similar four-helix bundle domains. The overall structure and the GxHxxE motif region differ from known HxxE metallopeptidases, suggesting that imelysin-like proteins are not peptidases. A putative functional site is located at the domain interface. We have now organized the known homologous proteins into a superfamily, which can be separated into four families. These families share a similar functional site, but each has family-specific structural and sequence features. These results indicate that imelysin-like proteins have evolved from a common ancestor, and likely have a conserved function.     

Multiple Reaction Monitoring-based, Multiplexed, Absolute Quantitation of 45 Proteins in Human Plasma

Mass spectrometry-based multiple reaction monitoring (MRM) quantitation of proteins can dramatically impact the discovery and quantitation of biomarkers via rapid, targeted, multiplexed protein expression profiling of clinical samples. A mixture of 45 peptide standards, easily adaptable to common plasma proteomics work flows, was created to permit absolute quantitation of 45 endogenous proteins in human plasma trypsin digests. All experiments were performed on simple tryptic digests of human EDTA-plasma without prior affinity depletion or enrichment. Stable isotope-labeled standard peptides were added immediately following tryptic digestion because addition of stable isotope-labeled standard peptides prior to trypsin digestion was found to generate elevated and unpredictable results. Proteotypic tryptic peptides containing isotopically coded amino acids ([¹³C₆]Arg or [¹³C₆]Lys) were synthesized for all 45 proteins. Peptide purity was assessed by capillary zone electrophoresis, and the peptide quantity was determined by amino acid analysis. For maximum sensitivity and specificity, instrumental parameters were empirically determined to generate the most abundant precursor ions and y ion fragments. Concentrations of individual peptide standards in the mixture were optimized to approximate endogenous concentrations of analytes and to ensure the maximum linear dynamic range of the MRM assays. Excellent linear responses (r > 0.99) were obtained for 43 of the 45 proteins with attomole level limits of quantitation (<20% coefficient of variation) for 27 of the 45 proteins. Analytical precision for 44 of the 45 assays varied by <10%. LC-MRM/MS analyses performed on 3 different days on different batches of plasma trypsin digests resulted in coefficients of variation of <20% for 42 of the 45 assays. Concentrations for 39 of the 45 proteins are within a factor of 2 of reported literature values. This mixture of internal standards has many uses and can be applied to the characterization of trypsin digestion kinetics and plasma protein expression profiling because 31 of the 45 proteins are putative biomarkers of cardiovascular disease.MS is capable of sensitive and accurate protein quantitation based on the quantitation of proteolytic peptides as surrogates for the corresponding intact proteins. Over the past 10 years, MS-based protein quantitation based on the analysis of peptides (in other words, based on “bottom-up” proteomics) has had a profound impact on how biological problems can be addressed (1, 2). Although advances in MS instrumentation have contributed to the improvement of MS-based protein quantitation, the use of stable isotopes in quantitative work flows has arguably had the greatest impact in improving the quality and reproducibility of MS-based protein quantitation (3–5).The ongoing development of untargeted MS-based quantitation work flows has focused on increasingly exhaustive sample prefractionation methods, at both the protein and peptide levels, with the goal of detecting and quantifying entire proteomes (6). Although untargeted MS-based quantitation work flows have their utility, they are costly in terms of lengthy MS data acquisition and analysis times, and as a result, they are often limited to quantifying differences between small sample sets (n < 10). To facilitate rapid quantitation of larger, clinically relevant sample sets (n > 100) there is a need to both simplify sample preparation and reduce MS analysis time.Multiple reaction monitoring (MRM)¹ is a tandem MS (MS/MS) scan mode unique to triple quadrupole MS instrumentation that is capable of rapid, sensitive, and specific quantitation of analytes in highly complex sample matrices (7). MRM is a targeted approach that requires knowledge of the molecular weight of an analyte and its fragmentation behavior under CID. MRM is capable of highly reproducible concentration determination when stable isotope-labeled internal standards are included in work flows and has been used for decades for the quantitation of low molecular mass analytes (<1000 Da) in pharmaceutical, clinical, and environmental applications (7, 8).The combination of triple quadrupole MS instrumentation with nanoliter flow rate high performance LC and nanoelectrospray ionization provides the necessary sensitivity for detection and quantitation of biological molecules such as peptides in complex samples such as plasma by MRM. When combined with the use of isotopically labeled synthetic peptide standards, MRM analysis is capable of sensitive (attomole level) and absolute determination of peptide concentrations across a wide concentration scale spanning a dynamic range of 10³–10⁴ (1, 9–13).Several recent studies involving MRM-based analysis of plasma proteins have focused on increasing MRM detection sensitivity by fractionating plasma using either multidimensional liquid chromatography, affinity depletion of high abundance proteins (11, 14, 15), or affinity enrichment of low abundance peptides (16, 17). Anderson and Hunter (14) have shown that LC-MRM/MS analysis is capable of detecting 47 moderate to high abundance proteins in plasma without depletion even though ∼90% of the total protein by weight in trypsin-digested plasma can be attributed to 10 high abundance proteins (18).Relative abundance of a protein does not preclude its involvement in disease. In fact, 32 of the 47 plasma proteins detected by Anderson and Hunter (14) have been implicated as putative markers for cardiovascular disease. The ability to rapidly quantify proteins in a highly multiplexed manner using MRM and internal standard peptides expands the potential application of MRM quantitation beyond biomarker validation and into the field of biomarker discovery. Targeted, simultaneous quantitation of hundreds of proteins in a single analysis will enable rapid protein expression profiling of large (n > 100) clinically relevant sample sets in a manner similar to DNA microarray expression profiling. By allowing researchers to look at patterns of expression levels of a large number of proteins in a large number of samples (as opposed to looking at the expression levels of only a single protein), multiplexed MRM-based quantitation will allow the correlation of expression patterns with particular diseases. Once these characteristic patterns have been established, physicians will be able to use these protein expression patterns to diagnose diseases in the same way they currently use blood chemistry panels or comprehensive metabolic panels.When considering the clinical utility of MS-based assays, direct comparisons are often made to ELISA, which is considered the “gold standard” for protein quantitation in clinical samples. Attributes of ELISAs, such as “time to first result” (1–2 h (19)) and the ability to quantify 96 or 384 samples in parallel because of their microtiter plate-based format, are currently difficult to match with MS-based protein assays. However, MRM protein assays may surpass ELISA in the rapid development of clinically useful, multiplexed protein assays. The impact of multiplexed assays in the field of genomics has increased interest in multiplexed quantitation of many proteins in individual clinical samples (19). Development and characterization of MRM-based protein assays using isotopically labeled peptides is rapid and inexpensive compared with the time and cost associated with the generation and characterization of antibodies for ELISA development.In this study, we describe the creation of a customizable mixture of concentration-balanced stable isotope-labeled standard (SIS) peptides representing an initial panel of 45 human plasma proteins. We used this mixture of SIS peptides to develop a suite of multiplexed, rapid, and reproducible MRM-based assays for expression profiling of these 45 proteins in simple tryptic digests of whole plasma. Additionally we characterized the analytical performance of these MRM peptide assays with respect to their reproducibility, and we demonstrated their utility for absolute protein concentration determination.Multiplexed MRM quantitation of peptides for protein quantitation has the potential to replace iTRAQ or other isotope label and label-free quantitative proteomics approaches because the approach is much faster than these other methods (30–60 min per analysis compared with 4 days for LC-MALDI-based iTRAQ), has greater reproducibility (CV <5% versus iTRAQ CV >20%), and enables absolute quantitation (concentration and copy number versus only x-fold up- or down-regulated). Additionally MRM-based quantitation with SIS peptides does not “miss” peptides because the SIS peptide must be detected in every sample: this means that if an endogenous peptide is not observed then it is below the limit of detection.     

Synthetic biology of proteins: tuning GFPs folding and stability with fluoroproline

Background

Proline residues affect protein folding and stability via cis/trans isomerization of peptide bonds and by the C^γ-exo or -endo puckering of their pyrrolidine rings. Peptide bond conformation as well as puckering propensity can be manipulated by proper choice of ring substituents, e.g. C^γ-fluorination. Synthetic chemistry has routinely exploited ring-substituted proline analogs in order to change, modulate or control folding and stability of peptides.

Methodology/Principal Findings

In order to transmit this synthetic strategy to complex proteins, the ten proline residues of enhanced green fluorescent protein (EGFP) were globally replaced by (4R)- and (4S)-fluoroprolines (FPro). By this approach, we expected to affect the cis/trans peptidyl-proline bond isomerization and pyrrolidine ring puckering, which are responsible for the slow folding of this protein. Expression of both protein variants occurred at levels comparable to the parent protein, but the (4R)-FPro-EGFP resulted in irreversibly unfolded inclusion bodies, whereas the (4S)-FPro-EGFP led to a soluble fluorescent protein. Upon thermal denaturation, refolding of this variant occurs at significantly higher rates than the parent EGFP. Comparative inspection of the X-ray structures of EGFP and (4S)-FPro-EGFP allowed to correlate the significantly improved refolding with the C^γ-endo puckering of the pyrrolidine rings, which is favored by 4S-fluorination, and to lesser extents with the cis/trans isomerization of the prolines.

Conclusions/Significance

We discovered that the folding rates and stability of GFP are affected to a lesser extent by cis/trans isomerization of the proline bonds than by the puckering of pyrrolidine rings. In the C^γ-endo conformation the fluorine atoms are positioned in the structural context of the GFP such that a network of favorable local interactions is established. From these results the combined use of synthetic amino acids along with detailed structural knowledge and existing protein engineering methods can be envisioned as a promising strategy for the design of complex tailor-made proteins and even cellular structures of superior properties compared to the native forms.