Functions of Manduca sexta Hemolymph Proteinases HP6 and HP8 in Two Innate Immune Pathways

Serine proteinases in insect plasma have been implicated in two types of immune responses; that is, activation of prophenoloxidase (proPO) and activation of cytokine-like proteins. We have identified more than 20 serine proteinases in hemolymph of the tobacco hornworm, Manduca sexta, but functions are known for only a few of them. We report here functions of two additional M. sexta proteinases, hemolymph proteinases 6 and 8 (HP6 and HP8). HP6 and HP8 are each composed of an amino-terminal clip domain and a carboxyl-terminal proteinase domain. HP6 is an apparent ortholog of Drosophila Persephone, whereas HP8 is most similar to Drosophila and Tenebrio spätzle-activating enzymes, all of which activate the Toll pathway. proHP6 and proHP8 are expressed constitutively in fat body and hemocytes and secreted into plasma, where they are activated by proteolytic cleavage in response to infection. To investigate activation and biological activity of HP6 and HP8, we purified recombinant proHP8, proHP6, and mutants of proHP6 in which the catalytic serine was replaced with alanine, and/or the activation site was changed to permit activation by bovine factor Xa. HP6 was found to activate proPO-activating proteinase (proPAP1) in vitro and induce proPO activation in plasma. HP6 was also determined to activate proHP8. Active HP6 or HP8 injected into larvae induced expression of antimicrobial peptides and proteins, including attacin, cecropin, gloverin, moricin, and lysozyme. Our results suggest that proHP6 becomes activated in response to microbial infection and participates in two immune pathways; activation of PAP1, which leads to proPO activation and melanin synthesis, and activation of HP8, which stimulates a Toll-like pathway.Innate immune systems of mammals and arthropods include extracellular serine proteinase cascade pathways, which rapidly amplify responses to infection and stimulate killing of pathogens. These proteinase-driven processes include the complement system of vertebrates (1, 2) and pathways in arthropods involving proteinases containing amino-terminal clip domains (3). Clip domain proteinases function in blood coagulation (4, 5), activation of prophenoloxidase (proPO) that leads to melanin synthesis (6–9), and stimulation of the Toll pathway to promote synthesis of antimicrobial peptides/proteins (AMPs)² secreted into the hemolymph (10, 11).The serine proteinase systems best characterized in arthropods are the horseshoe crab hemolymph coagulation pathway and the cascade leading to activation of the Toll pathway in dorsal-ventral development in Drosophila (12–14). Recent research also has led to better characterization of the proPO activation pathway in Manduca sexta (7, 15, 16) and the Toll-signaling pathway in the Drosophila immune response (17, 18) and to both the proPO and Toll pathways in the beetle Tenebrio molitor (11, 19).In the proPO activation pathway, soluble pattern recognition proteins initially recognize pathogen-associated molecular patterns such as bacterial peptidoglycan or fungal β-1,3-glucan (20–22). This interaction stimulates the sequential activation of a series of serine proteinases in hemolymph, leading to the activation of proPO-activating proteinase (PAP), also known as proPO activating enzyme (7, 23). Activated PAP converts inactive proPO to PO. PO catalyzes the hydroxylation of monophenols to o-diphenols and the oxidation of o-diphenols to quinones that are involved in microbial killing, melanin synthesis, sequestration of parasites or pathogens, and wound healing (24, 25). Other proteins required for proPO activation are clip-domain serine proteinase homologs (SPHs), whose catalytic serine is replaced with glycine and, therefore, lack proteolytic activity (26, 27). Serine proteinase inhibitors, including members of the serpin superfamily, regulate the activation of proPO by inhibiting the activating proteinases (28, 29).Drosophila clip-domain serine proteinases Persephone, Grass, Spirit, and spätzle-processing enzyme (SPE) participate in the activation of Toll pathway, stimulating synthesis of antimicrobial peptides as an innate immune response (18, 30–32). Although genetic evidence indicates that Persephone and Spirit are upstream of SPE in the cascade, the substrate(s) of Persephone and Spirit have not been identified, and which proteinase directly activates SPE is unknown. Neither is it clear whether these enzymes may be related to the melanization pathway, which involves clip-domain proteinases MP2 and MP1 (33).Here we report the functional characterization of M. sexta HP6 and HP8, probable orthologs of Drosophila Persephone and SPE, respectively. We developed methods to activate purified recombinant proHP6 and proHP8 and discovered that HP6 participates in proPO activation by activating proPAP1 and that both HP6 and HP8 function in a pathway that stimulates the synthesis of AMPs in M. sexta.     

FANCI Binds Branched DNA and Is Monoubiquitinated by UBE2T-FANCL

FANCI is integral to the Fanconi anemia (FA) pathway of DNA damage repair. Upon the occurrence of DNA damage, FANCI becomes monoubiquitinated on Lys-523 and relocalizes to chromatin, where it functions with monoubiquitinated FANCD2 to facilitate DNA repair. We show that FANCI and its C-terminal fragment possess a DNA binding activity that prefers branched structures. We also demonstrate that FANCI can be ubiquitinated on Lys-523 by the UBE2T-FANCL pair in vitro. These findings should facilitate future efforts directed at elucidating molecular aspects of the FA pathway.Fanconi anemia (FA)⁴ is characterized by developmental defects, bone marrow failure, and a strong predisposition to cancer. FA cells exhibit exquisite sensitivity to DNA cross-linking agents and marked genomic instability, indicative of a failure to repair damaged DNA (1–3). Thirteen FA proteins have been identified, of which eight, FANC-A, -B, -C, -E, -F, -G, -L, and -M, form part of a nuclear core complex that is required to monoubiquitinate two other FA proteins, FANCD2 and FANCI. When monoubiquitinated, FANCD2 and FANCI become chromatin-associated in foci that contain various factors, including the RAD51 recombinase BRCA2 (also known as FANCD1) and PALB2 (also called FANCN), which mediate DNA repair via RAD51-catalyzed homologous recombination (4).Monoubiquitination of FANCD2 appears to be a key event for proper repair of exogenous DNA damage but also occurs during an unperturbed S phase, likely in response to stalled replication forks (4–7). FANCD2 monoubiquitination depends on the E3 ligase activity of FANCL (8) and on the E2 ubiquitin-conjugating enzyme, UBE2T (9). In vitro, FANCL and UBE2T can monoubiquitinate chicken FANCD2 (10).FANCI was identified recently as a target protein for the ATM/ATR kinase. FANCI is also monoubiquitinated, in a manner that is dependent on the FA core complex (11). In cells, a fraction of FANCD2 and FANCI associates in a complex. Moreover, the amount and monoubiquitination of these two FA proteins are co-dependent in human cells, i.e. the quantity and monoubiquitination of FANCD2 are diminished in FANCI-deficient cells and vice versa (11–14). These observations suggest that FANCI and FANCD2 form a complex integral to cellular DNA repair capacity. Mutating the ubiquitinated target lysine of FANCI (Lys-523) renders cells sensitive to DNA damage and impairs the assembly of DNA damage-induced nuclear foci of FANCD2 and FANCI (11, 14). Herein, we document studies that reveal several biochemical attributes of FANCI, including DNA binding, and its monoubiquitination, that are relevant for understanding the biological role of this key FA protein.     

Tubacin Kills Epstein-Barr Virus (EBV)-Burkitt Lymphoma Cells by Inducing Reactive Oxygen Species and EBV Lymphoblastoid Cells by Inducing Apoptosis

Tubacin is a small molecule inhibitor of histone deacetylase 6 and blocks aggresome activity. We found that Epstein-Barr virus (EBV)-positive Burkitt lymphoma (BL) cells were generally killed by lower doses of tubacin than EBV-transformed lymphoblastoid cells (LCLs) or EBV-negative BL cells. Tubacin induced apoptosis of LCLs, which was inhibited by pretreatment with a pancaspase inhibitor but not by butylated hydroxyanisole, which inhibits reactive oxygen species. In contrast, tubacin killed EBV-positive BL cells in a caspase-3-independent pathway that involved reactive oxygen species and was blocked by butylated hydroxyanisole. Previously, we showed that bortezomib, a proteasome inhibitor, induces apoptosis of EBV LCLs and that LCLs are killed by lower doses of bortezomib than EBV-positive BL cells. Here we found that the combination of bortezomib and tubacin acted in synergy to kill EBV-positive BL cells and LCLs. Tubacin or the combination of bortezomib and tubacin did not induce EBV lytic replication. These findings suggest that the combination of a proteasome inhibitor and an HDAC6 inhibitor may represent a useful strategy for the treatment of certain EBV-associated B cell lymphomas.Epstein-Barr virus (EBV)⁴ is associated with several human lymphoid malignancies, including Hodgkin disease, Burkitt lymphoma (BL), T cell lymphomas, and post-transplant lymphoproliferative disease (1, 2). Tissues from patients with EBV post-transplant lymphoproliferative disease typically have a type 3 latency pattern in which each of the EBV latency-associated proteins, including EBV nuclear antigens (EBNA-1, -2, -3A, -3B, and -3C) and latent membrane proteins (LMP1 and LMP2) are expressed. A type 3 latency pattern is also seen in lymphoblastoid cell lines (LCLs), derived from primary B cells transformed with EBV in vitro. Tissues from patients with EBV-positive BL usually have a type 1 latency pattern with expression of EBNA-1 but not the other latency-associated proteins. When grown in cell culture, BL cell lines can have a type 1 or a type 3 pattern of latency.The treatment of EBV-associated lymphoid malignancies often requires cytotoxic chemotherapy, which is not always successful. Inhibition of proteasomes and aggresomes represents new therapeutic targets for malignancies (3–5). Degradation of proteins is required for vital cell functions and is carried out both in proteasomes and aggresomes. Misfolded or unfolded proteins are polyubiquitinated by a complex of proteins and subsequently degraded by proteasomes. However, if ubiquitinated proteins escape degradation by proteasomes and aggregate, they accumulate into aggresomes (6). Aggresome formation can be abrogated by disrupting the microtubule cytoskeleton or by overexpression of the p50 subunit of dynactin (7). HDAC6 (histone deacetylase 6) is a microtubule-associated deacetylase that can induce microtubule disassembly and promote chemotactic cell motility (8–10). HDAC6 contains a dynein motor binding domain, two catalytic domains with histone deacetylase activity, and a carboxyl-terminal domain that binds polyubiquitinated misfolded proteins (11). The carboxyl catalytic domain of HDAC6 possesses α-tubulin deacetylase activity (12). HDAC6 is required for transport of misfolded proteins for aggresome formation and to prevent apoptosis in response to misfolded protein stress (11). HDAC6 inhibitors disrupt aggresomes (5). Tubacin inhibits the carboxyl catalytic domain of HDAC6, increases the level of acetylated α-tubulin, and blocks aggresome activity (4, 12, 13).Bortezomib is an inhibitor of the 26 S proteasome (3). Previously, we showed that bortezomib induces apoptosis of EBV-transformed B cells and prolongs survival of mice inoculated with EBV-transformed B cells (14). In contrast, EBV-negative Burkitt lymphoma cells were much less sensitive to killing by bortezomib. Since bortezomib has been shown to interact synergistically with tubacin to induce apoptosis in multiple myeloma cells (4), we studied the effect of tubacin on EBV-transformed B cells and Burkitt lymphoma cells both in the absence and presence of bortezomib. We show that tubacin kills LCLs by apoptosis and induction of caspase-3, whereas tubacin kills EBV-positive BL cells by induction of reactive oxygen species. Bortezomib and tubacin acted in synergy to kill EBV-positive BL cells and LCLs. These findings suggest that the combination of tubacin and bortezomib may have potential as a model for the treatment of certain EBV-associated lymphomas.     

Characterization of the Endocannabinoid System in Human Neuronal Cells and Proteomic Analysis of Anandamide-induced Apoptosis

Anandamide (AEA) is an endogenous agonist of type 1 cannabinoid receptors (CB1R) that, along with metabolic enzymes of AEA and congeners, compose the “endocannabinoid system.” Here we report the biochemical, morphological, and functional characterization of the endocannabinoid system in human neuroblastoma SH-SY5Y cells that are an experimental model for neuronal cell damage and death, as well as for major human neurodegenerative disorders. We also show that AEA dose-dependently induced apoptosis of SH-SY5Y cells. Through proteomic analysis, we further demonstrate that AEA-induced apoptosis was paralleled by an ∼3 to ∼5-fold up-regulation or down-regulation of five genes; IgG heavy chain-binding protein, stress-induced phosphoprotein-1, and triose-phosphate isomerase-1, which were up-regulated, are known to act as anti-apoptotic agents; actin-related protein 2/3 complex subunit 5 and peptidylprolyl isomerase-like protein 3 isoform PPIL3b were down-regulated, and the first is required for actin network formation whereas the second is still function-orphan. Interestingly, only the effect of AEA on BiP was reversed by the CB1R antagonist SR141716, in SH-SY5Y cells as well as in human neuroblastoma LAN-5 cells (that express a functional CB1R) but not in SK-NBE cells (which do not express CB1R). Silencing or overexpression of BiP increased or reduced, respectively, AEA-induced apoptosis of SH-SY5Y cells. In addition, the expression of BiP and of the BiP-related apoptotic markers p53 and PUMA was increased by AEA through a CB1R-dependent pathway that engages p38 and p42/44 mitogen-activated protein kinases. Consistently, this effect of AEA was minimized by SR141716. In conclusion, we identified BiP as a key protein in neuronal apoptosis induced by AEA.Endocannabinoids bind to and activate both type 1 (CB1R)⁴ and type 2 (CB2R) cannabinoid receptors and are widely recognized as important regulators of central and peripheral functions (1–3). The most studied endocannabinoids are anandamide (N-arachidonoylethanolamine, AEA) and 2-arachidonoylglycerol (2-AG) (1, 3). AEA, unlike 2-AG, binds to and activates also transient receptor potential vanilloid 1 (TRPV1), thus being considered a true “endovanilloid” (4).The “endocannabinoid system (ECS)” includes the receptors, their ligands AEA and 2-AG, and the enzymes that synthesize (N-acyl-phosphatidylethanolamine-hydrolyzing phospholipase D (NAPE-PLD) and diacylglycerol lipase (DAGL)) or degrade (fatty acid amide hydrolase (FAAH) and monoacylglycerol lipase (MAGL)) AEA and 2-AG, respectively (1–3). On the other hand, there is still controversy about the identity and even the existence of purported “endocannabinoid transporters” that have not yet been cloned, isolated, or characterized (5). A growing interest is concerned with the ability of AEA to induce apoptosis in neuronal and non-neuronal cells (for comprehensive reviews see Refs. 6–9). Such a pro-apoptotic activity of AEA appears to be mediated by divergent pathways, each potentiated, reduced, or unaffected by cannabinoid or TRPV1 receptors (6–9). They can also be dependent on membrane cholesterol content (10, 11), generation of reactive oxygen species (12, 13), or even release of ethanolamine from AEA catalyzed by FAAH (14). In this context, it should be stressed that data on ECS and AEA-induced apoptosis in human neuronal cells are still very scant. Furthermore, a proteomic analysis of AEA-induced apoptosis has never been performed, leaving open the question of which proteins (if any) might be modulated at the level of expression upon induction of programmed cell death by this endocannabinoid. On this basis, we sought to characterize through functional and immunochemical assays and confocal microscopy the ECS components in human neuroblastoma SH-SY5Y cells. In addition, we performed a proteomic analysis of AEA-induced apoptosis in these cells that identified five proteins whose expression was modified. Among these proteins, one (BiP/GRP78) was shown to be modulated by AEA in a CB1R-dependent manner, in parallel with apoptosis. Through silencing and overexpression experiments, it was found to be a key player in the death program.     

Identification of Lysine Succinylation Substrates and the Succinylation Regulatory Enzyme CobB in Escherichia coli

Lysine succinylation is a newly identified protein post-translational modification pathway present in both prokaryotic and eukaryotic cells. However, succinylation substrates and regulatory enzyme(s) remain largely unknown, hindering the biological study of this modification. Here we report the identification of 2,580 bacterial lysine succinylation sites in 670 proteins and 2,803 lysine acetylation (Kac) sites in 782 proteins, representing the first lysine succinylation dataset and the largest Kac dataset in wild-type E. coli. We quantified dynamic changes of the lysine succinylation and Kac substrates in response to high glucose. Our data showed that high-glucose conditions led to more lysine-succinylated proteins and enhanced the abundance of succinyllysine peptides more significantly than Kac peptides, suggesting that glucose has a more profound effect on succinylation than on acetylation. We further identified CobB, a known Sir2-like bacterial lysine deacetylase, as the first prokaryotic desuccinylation enzyme. The identification of bacterial CobB as a bifunctional enzyme with lysine desuccinylation and deacetylation activities suggests that the eukaryotic Kac-regulatory enzymes may have enzymatic activities on various lysine acylations with very different structures. In addition, it is highly likely that lysine succinylation could have unique and more profound regulatory roles in cellular metabolism relative to lysine acetylation under some physiological conditions.Lysine acetylation (Kac)¹ is a dynamic and evolutionarily conserved post-translational modification (PTM) that is known to be involved in the regulation of diverse cellular processes (1–9). The status of this modification is controlled by two groups of enzymes with opposing enzymatic activities, lysine acetyltransferases that add an acetyl group to the lysine (Lys or K) residue, and histone lysine deacetylases (HDACs) that remove the acetyl group (10–16). HDACs are grouped into several categories (17): class I (HDAC1, -2, -3, and -8), class IIA (HDAC4, -5, -7, and -9), class IIB (HDAC6 and -10), class III (Sirt1–7), and class IV (HDAC11). The weak deacetylation activities of some HDACs (e.g. Sirt4–7 and HDAC4, -5, and -7–11), as well as the demonstration of Sirt5 as a desuccinylation and demalonylation enzyme, suggest that some HDAC enzymes have activities that are independent of acetylation (18, 19).For a long period of time, lysine acetylation was considered as a protein modification that was restricted to nuclei (20). The identification of cytosolic Kac substrates and the localization of some HDACs outside nuclei suggest a non-nuclear function of lysine acetylation (13, 21, 22). The first proteomic screening identified hundreds of substrate proteins in cytosolic and mitochondrial fractions and demonstrated high abundance of Kac in mitochondrial proteins and metabolic enzymes (23). This result implies that Kac has diverse non-nuclear roles and can regulate functions of metabolism and mitochondria (23). Since then, we and others have extensively characterized the cellular acetylome (5, 9, 24–26).The lysine succinylation (Ksucc) and lysine malonylation pathways are two PTM pathways that were recently identified and comprehensively validated in both bacterial and mammalian cells, with multiple substrate proteins identified, using HPLC-MS/MS, co-elution of synthetic peptides, isotopic labeling, Western blotting analysis using pan-anti-Ksucc antibodies, and proteomics analysis (18, 27). We also showed that Ksucc is present in core histones (29). In yeast histones, some Ksucc sites are located in regions where histones make close contact with DNA, suggesting that Ksucc sites may be involved in gene regulation by changing the chromatin structure (29). We then found that Sirt5, a member of the class III family of HDACs, can function as a desuccinylation enzyme in vitro and in vivo (18, 19). In a recent study, we revealed that Sirt5 is a key regulatory enzyme of Ksucc and that Ksucc proteins are abundant among a group of mitochondrial enzymes that are predominantly involved in fatty acid metabolism, amino acid degradation, and the tricarboxylic acid cycle (28). Importantly, Ksucc is very dynamic not only in mammalian cells, but also in bacteria (27, 29). These lines of evidence strongly suggest that lysine succinylation is likely an important PTM in the regulation of cellular functions.Although key elements of the Ksucc pathway are being identified in mammalian cells, their counterparts in bacteria remain largely unknown. We and others have used a proteomics approach to identify Kac substrates in bacteria (26, 30, 31, 52). The Sir2-like enzyme CobB is the best-studied protein deacetylase in bacteria (8). CobB was initially identified as an enzyme required for the activation of acetyl-CoA synthetase (8). Recently, CobB was shown to play roles in bacterial energy metabolism (31) and stress response (32). Those studies indicated that Kac is an evolutionarily conserved PTM with a role in energy metabolism in prokaryotes. Nevertheless, dynamic changes of lysine acetylation in bacteria have not been studied. In addition, substrates of lysine succinylation and their regulatory enzymes are not known.In this paper, we report a quantitative proteomic approach based on stable isotope labeling by amino acids in cell culture (SILAC) to identify and quantify changes in bacterial lysine succinylation, as well as lysine acetylation, in response to glucose, a major energy source. Our screening detected 2,580 lysine-succinylated sites in 670 proteins and 2,803 Kac sites in 782 proteins in Escherichia coli. Our quantitative proteomics data show that glucose had a more profound effect on Ksucc than on Kac. In addition, we found that CobB, a known prokaryotic deacetylase, had dual enzymatic activities to catalyze the removal of two structurally different lysine acyl groups, acetyl and succinyl, from the modified lysine residues.     

Molecular Requirements for Sorting of the Chemokine Interleukin-8/CXCL8 to Endothelial Weibel-Palade Bodies

Sorting of proteins to Weibel-Palade bodies (WPB) of endothelial cells allows rapid regulated secretion of leukocyte-recruiting P-selectin and chemokines as well as procoagulant von Willebrand factor (VWF). Here we show by domain swap studies that the exposed aspartic acid in loop 2 (Ser⁴⁴-Asp⁴⁵-Gly⁴⁶) of the CXC chemokine interleukin (IL)-8 is crucial for targeting to WPB. Loop 2 also governs sorting of chemokines to α-granules of platelets, but the fingerprint of the loop 2 of these chemokines differs from that of IL-8. On the other hand, loop 2 of IL-8 closely resembles a surface-exposed sequence of the VWF propeptide, the region of VWF that directs sorting of the protein to WPB. We conclude that loop 2 of IL-8 constitutes a critical signal for sorting to WPB and propose a general role for this loop in the sorting of chemokines to compartments of regulated secretion.The regulated secretion of proteins from vascular endothelial cells provides a mechanism for their rapid delivery in response to secretagogues (1–4). The best characterized organelle for such secretion is the cigar-shaped Weibel-Palade body (WPB)³ that contains a number of proteins important in hemostasis and inflammation. For example, release of WPB is most likely involved in the early events of acute inflammation, since P-selectin stored in this compartment (5) mediates the tethering and rolling of leukocytes (6) and even appears to be the dominant selectin involved in ischemia/reperfusion injury (7, 8). Moreover, we and others have previously shown that the chemokines interleukin-8 (IL-8)/CXCL8 (9, 10) and eotaxin-3/CCL26 (11) can also be stored in WPB and hence are prime candidates for converting the selectin-mediated rolling of leukocytes into integrin-mediated firm adhesion. In this respect, WPB can be considered a “Swiss army knife of leukocyte recruitment,” able to rapidly deliver selectins and chemokines to the surface of endothelial cells that constitutively express the integrin ligands intercellular adhesion molecule-1 and -2.Targeting of proteins to compartments of regulated secretion is postulated to be an active process where proteins are segregated from the default route of exocytosis, the constitutive secretory pathway (12). The formation of WPB appears to be triggered by the expression of its main constituent, the 350-kDa hemostatic glycoprotein von Willebrand factor (VWF) (1, 13, 14). VWF entails a large propeptide (741 amino acids) that has been shown to be crucial for both the sorting of VWF (14, 15) and its multimerization (13, 14). Interaction of the propeptide and the mature part of VWF is moreover required for the formation of WPB in endothelial cells (16). Multimerization and organization of VWF and its propeptide into tubules takes place in the trans-Golgi network (TGN) and is followed by the formation of an extensive coat of AP-1/clathrin around the emerging organelles (17). Furthermore, it appears that other molecules can be targeted to WPB by interaction with VWF. For osteoprotegerin (18) and P-selectin (5, 19), this probably happens at the TGN level. IL-8 also binds to VWF under conditions mimicking those of the TGN, and subcellular fractionation analysis revealed that IL-8 is stored in a stoichiometric ratio to VWF, suggesting a direct molecular interaction (20).Mechanisms of chemokine sorting to the regulated secretory pathway are currently not well understood, but recent data from blood platelets point to a role for an exposed loop between the second and third β-strands of the molecule, referred to as loop 2 or the 40s loop, in the sorting of PF4/CXCL4, RANTES/CCL5, and NAP-2/CXCL7 to platelet α-granules (21). Specifically, the sorting of PF4 appears to depend on loop 2, featuring the residues ⁴⁵Leu-Lys-Asn-Gly⁴⁸ (21), and loops with similar three-dimensional structures are also found in RANTES and NAP-2, suggesting that this motif may be of general significance for chemokine sorting in platelets (21). In this regard, it may be of relevance that GROα (growth-related oncogene α)/CXCL1 contains a loop 2 sequence identical to that of PF4 and is found together with MCP-1 (monocyte chemotactic protein-1)/CCL2 in a recently characterized endothelial compartment for regulated secretion that we have designated type II granules of regulated secretion (11, 22).The aim of this study was to elucidate the molecular properties of IL-8 that enable its targeting to endothelial WPB. Chemokines have a highly similar tertiary structure, consisting of a typical Greek key structural motif with three consecutive β-strands forming a β-sheet stabilized by one or two disulfide bridges and a C-terminal α-helix inclined at a 45° angle to the β-sheet (Fig. 2, A and B) (23). This similarity in protein fold and the existence of endothelial cell-derived chemokines that are not sorted to WPB (11) make them ideal candidates for domain swap studies. By means of alanine mutations or chimerization with IP-10 (interferon-γ-induced protein-10), a chemokine not targeted to WPB (11), we demonstrated that loop 2 of IL-8, consisting of the residues Ser⁴⁴-Asp⁴⁵-Gly⁴⁶, is essential for sorting of the chemokine to WPB. Moreover, a chimera containing loop 2 and the α-helix from IL-8 on an IP-10 backbone sorted to WPB with the same efficiency as IL-8. The loop 2 area of IL-8 maintains a neutral net charge, and we propose that WPB targeting of IL-8 can occur when the overall charge is neutral or negative, whereas a positive charge is not tolerated. The fingerprint of the loop 2 region differs among chemokines and may confer specificity for sorting.Open in a separate windowFIGURE 2.Structural properties and distribution of IL-8 and IP-10 constructs and IL-8/IP-10 chimeras in HUVECs. A and B, IL-8 shares the characteristic secondary structure of most chemokines, with an N-terminal flexible region culminating in an N-loop region and a short 3₁₀-helix, followed by three anti-parallel β-strands and a C-terminal α-helix. Loop 2 is located between strands β-2 and β-3. IL-8 may form homodimers, in which case two β1-strands align to form an extended six-stranded β-sheet. Loop 2 of each monomer is exposed on opposite sides of the dimer. All central hydrophobic amino acid side chains making up the protein core connecting the β-sheet and α-helices of the two peptide chains are shown in ball-and-stick representations. The viewpoint in B is rotated 90° relative to A. C, transfected HUVECs were immunostained for a construct-derived HA tag (monoclonal antibody HA-7 or HA.11; green) and for VWF (red) as a marker of WPB. WT IL-8 colocalized with VWF, as demonstrated by the presence of yellow WPB (top). Mutation of Asp⁴⁵ in loop 2 of IL-8 to K (D45K) arrested WPB localization. As previously shown, IP-10 does not colocalize with VWF. However, residues 23–51 of IL-8 (Ch4), loop 2 of IL-8 in combination with loop 3 of IL-8 (Ch8), or the residues of loop 2 of IL-8 plus the C-terminal α-helix of IL-8 (Ch9) grafted to IP-10 restored sorting to WPB. The corner insets show high magnification of framed areas. Scale bar, 10 μm.