Role of Lysyl Oxidase Propeptide in Secretion and Enzyme Activity

Lysyl oxidase (LOX) is secreted as a proenzyme (proLOX) that is proteolytically processed in the extracellular milieu to release the propeptide and mature, active LOX. LOX oxidizes lysyl residues of a number of protein substrates in the extracellular matrix and on the cell surface, which impacts several physiological and disease states. Although the LOX propeptide (LOX‐PP) is glycosylated, little is known about the role of this modification in LOX secretion and activity. To gain insight into this issue, cells were transfected with native, full‐length LOX cDNA (pre‐pro‐LOX), the N‐glycosylation null pre‐[N/Q]pro‐LOX cDNA and the deletion mutant pre‐LOX cDNA, referred to as secretory LOX, in which mature LOX is targeted to the secretory pathway without its N‐terminal propeptide sequence. The results show that glycosylation of the LOX‐PP is not required for secretion and extracellular processing of pro‐LOX but it is required for optimal enzyme activity of the resulting mature LOX. Complete deletion of the propeptide sequence prevents mature LOX from exiting the endoplasmic reticulum (ER). Taken together, our study points out the requirement of the LOX‐PP for pro‐LOX exit from the ER and is the first to highlight the influence of LOX‐PP glycosylation on LOX enzyme activity. J. Cell. Biochem. 111: 1231–1243, 2010. © 2010 Wiley‐Liss, Inc.     

Synthesis and biological activity of N4-phenylsubstituted-6-(2,4-dichloro phenylmethyl)-7H-pyrrolo[2,3-d]pyrimidine-2,4-diamines as vascular endothelial growth factor receptor-2 inhibitors and antiangiogenic and antitumor agents

A series of eight N⁴-phenylsubstituted-6-(2,4-dichlorophenylmethyl)-7H-pyrrolo[2,3-d]pyrimidine-2,4-diamines 8–15 were synthesized as vascular endothelial growth factor receptor-2 (VEGFR-2) inhibitors with varied substitutions in the phenyl ring of the 4-anilino moiety. In addition, five N⁴-phenylsubstituted-6-phenylmethylsubstituted-7H-pyrrolo[2,3-d]pyrimidin-4-amines 16–20 were synthesized to evaluate the importance of the 2-NH₂ moiety for multiple receptor tyrosine kinase (RTK) inhibition. Cyclocondensation of α-halomethylbenzylketones with 2,6-diamino-4-hydroxypyrimidine afforded 2-amino-6-(2,4-dichlorophenylmethyl)-3,7-dihydro-4H-pyrrolo[2,3-d]pyrimidin-4-one, 23 and reaction of α-bromomethylbenzylketones with ethylamidinoacetate followed by cyclocondensation with formamide afforded the 6-phenylmethylsubstituted-3,7-dihydro-4H-pyrrolo[2,3-d]pyrimidin-4-ones, 40–42, respectively. Chlorination of the 4-position and displacement with appropriate anilines afforded the target compounds 8–20. Compounds 8, 10 and 14 were potent VEGFR-2 inhibitors and were 100-fold, 40-fold and 8-fold more potent than the standard semaxanib, respectively. Previously synthesized multiple RTK inhibitor, 5 and the VEGFR-2 inhibitor 8 from this study, were chosen for further evaluation in a mouse orthotopic model of melanoma and showed significant inhibition of tumor growth, angiogenesis and metastasis.     

Birds adjust acoustic directionality to beam their antipredator calls to predators and conspecifics

Animals in many vertebrate species vocalize in response to predators, but it is often unclear whether these antipredator calls function to communicate with predators, conspecifics or both. We evaluated the function of antipredator calls in 10 species of passerines by measuring the acoustic directionality of these calls in response to experimental presentations of a model predator. Acoustic directionality quantifies the radiation pattern of vocalizations and may provide evidence about the receiver of these calls. We predicted that antipredator calls would have a lower directionality if they function to communicate with surrounding conspecifics, and a higher directionality and aimed at the receiver if they function to communicate with the predator. Our results support both of these functions. Overall, the birds produce antipredator calls that have a relatively low directionality, suggesting that the calls radiate in many directions to alert conspecifics. However, birds in some species increase the directionality of their calls when facing the predator. They can even direct their calls towards the predator when facing lateral to it—effectively vocalizing sideways towards the predator. These results suggest that antipredator calls in some species are used to communicate both to conspecifics and to predators, and that birds adjust the directionality of their calls with remarkable sophistication according to the context in which they are used.     

Comparative Genomic Analysis of 60 Mycobacteriophage Genomes: Genome Clustering, Gene Acquisition, and Gene Size

Mycobacteriophages are viruses that infect mycobacterial hosts. Expansion of a collection of sequenced phage genomes to a total of 60—all infecting a common bacterial host—provides further insight into their diversity and evolution. Of the 60 phage genomes, 55 can be grouped into nine clusters according to their nucleotide sequence similarities, 5 of which can be further divided into subclusters; 5 genomes do not cluster with other phages. The sequence diversity between genomes within a cluster varies greatly; for example, the 6 genomes in Cluster D share more than 97.5% average nucleotide similarity with one another. In contrast, similarity between the 2 genomes in Cluster I is barely detectable by diagonal plot analysis. In total, 6858 predicted open-reading frames have been grouped into 1523 phamilies (phams) of related sequences, 46% of which possess only a single member. Only 18.8% of the phams have sequence similarity to non-mycobacteriophage database entries, and fewer than 10% of all phams can be assigned functions based on database searching or synteny. Genome clustering facilitates the identification of genes that are in greatest genetic flux and are more likely to have been exchanged horizontally in relatively recent evolutionary time. Although mycobacteriophage genes exhibit a smaller average size than genes of their host (205 residues compared with 315), phage genes in higher flux average only 100 amino acids, suggesting that the primary units of genetic exchange correspond to single protein domains.     

Fusion-Deficient Insertion Mutants of Herpes Simplex Virus Type 1 Glycoprotein B Adopt the Trimeric Postfusion Conformation

Glycoprotein B (gB) enables the fusion of viral and cell membranes during entry of herpesviruses. However, gB alone is insufficient for membrane fusion; the gH/gL heterodimer is also required. The crystal structure of the herpes simplex virus type 1 (HSV-1) gB ectodomain, gB730, has demonstrated similarities between gB and other viral fusion proteins, leading to the hypothesis that gB is a fusogen, presumably directly involved in bringing the membranes together by refolding from its initial or prefusion form to its final or postfusion form. The only available crystal structure likely represents the postfusion form of gB; the prefusion form has not yet been determined. Previously, a panel of HSV-1 gB mutants was generated by using random 5-amino-acid-linker insertion mutagenesis. Several mutants were unable to mediate cell-cell fusion despite being expressed on the cell surface. Mapping of the insertion sites onto the crystal structure of gB730 suggested that several insertions might not be accommodated in the postfusion form. Thus, we hypothesized that some insertion mutants were nonfunctional due to being “trapped” in a prefusion form. Here, we generated five insertion mutants as soluble ectodomains and characterized them biochemically. We show that the ectodomains of all five mutants assume conformations similar to that of the wild-type gB730. Four mutants have biochemical properties and overall structures that are indistinguishable from those of the wild-type gB730. We conclude that these mutants undergo only minor local conformational changes to relieve the steric strain resulting from the presence of 5 extra amino acids. Interestingly, one mutant, while able to adopt the overall postfusion structure, displays significant conformational differences in the vicinity of fusion loops, relative to wild-type gB730. Moreover, this mutant has a diminished ability to associate with liposomes, suggesting that the fusion loops in this mutant have decreased functional activity. We propose that these insertions cause a fusion-deficient phenotype not by preventing conversion of gB to a postfusion-like conformation but rather by interfering with other gB functions.Herpes simplex virus type 1 (HSV-1) is the prototype of the diverse herpesvirus family that includes many notable human pathogens (26). In addition to the icosahedral capsid and the tegument that surround its double-stranded DNA genome, herpesviruses have an envelope—an outer lipid bilayer—bearing a number of surface glycoproteins. During infection, HSV-1 must fuse its envelope with a cellular membrane in order to deliver the capsid into a target host cell. Among its viral glycoproteins, only glycoprotein C (gC), gB, gD, gH, and gL participate in this entry process, and only the last four are required for fusion (28). Although gD is found only in alphaherpesviruses, all herpesviruses encode gB, gH, and gL, which constitute their core fusion machinery. Of these three proteins, gB is the most highly conserved.We recently determined the crystal structure of a nearly full-length ectodomain of HSV-1 gB, gB730 (18). The crystal structure of the ectodomain of gB from Epstein-Barr virus, another herpesvirus, has also been subsequently determined (4). The two structures showed similarities between gB and other viral fusion proteins, in particular, G from an unrelated vesicular stomatitis virus (VSV) (25), leading to the hypothesis that gB is a fusogen, presumably directly involved in bringing the viral and host cell membranes together to enable their fusion. However, gB alone is known to be insufficient for membrane fusion; the gH/gL heterodimer is also required. This insufficiency raises the question of exactly how gB functions during viral entry. Answering this question is critical for understanding the complex mechanism that herpesviruses use to enter their host cells.In acting as a viral fusogen, gB must undergo dramatic conformational changes, refolding through a series of conformational intermediates from its initial, or prefusion form, to its final, or postfusion form (15). These conformational changes are not only necessary to bring the two membranes into proximity; they are also thought to provide the energy for the fusion process. The prefusion form corresponds to the protein present on the viral surface prior to initiation of fusion. The postfusion form represents the protein after fusion of the viral and host cell membranes. The available gB structure likely represents its postfusion form, since it shares more in common with the postfusion rather than the prefusion structure of vesicular stomatitis virus (VSV) G (3, 17). However, the prefusion form has not yet been characterized.Recently, a panel of gB mutants was generated by using random linker-insertion mutagenesis (21). Of these mutants, 16 were particularly interesting because they were nonfunctional in cell-cell fusion assays despite being expressed on the cell surface at levels that indicate proper folding for transport. These observations suggested that each insertion somehow interfered with gB function. Insertions in 12 of these mutants are located within the available structure of the gB ectodomain, which allowed Lin and Spear to analyze their locations (21).The most prominent examples of such nonfunctional mutants are two mutants with insertions after residues I185 or E187, henceforth referred to as “cavity mutants” because both I185 and E187 point into a cavity inside the gB trimer (Fig. 1B and D). Although this cavity might accommodate a single 5-amino-acid insertion, it “is not large enough to accommodate three 5-amino-acid insertions” (21) that would be present in the trimer (one insertion per protomer).Open in a separate windowFIG. 1.Location of the insertion sites in the sequence of gB and the structure of the postfusion form of its ectodomain. (A) Linear diagram of the full-length gB with functional domains highlighted (as in reference 18). Domain I is shown in cyan, domain II in green, domain III in yellow, domain IV in orange, domain V in red, and the disordered region between domains II and III in purple. Regions absent from the crystal structure of gB730 are shown in gray. Sequences in the region of 5-amino-acid insertions (residues 181 to 190 and residues 661 to 680) are shown in black. Arrows mark the locations of 5-amino-acid insertions, shown as red text. (B) Crystal structure of gB730 (18). Residues preceding the 5-amino-acid insertions in mutants studied here are shown as spheres colored by domain, consistent with panel A. Boxes delineate the hinge region, enlarged in panel C, and the cavity region, enlarged in panel D. (C) Close-up view of the hinge region shown in molecular surface representation, with residues 663 to 675 displayed as sticks. Hydrophobic residues are colored orange. Residues preceding the 5-amino-acid insertions in mutants studied here are labeled with asterisks; remaining labels correspond to additional hydrophobic residues in the 663-675 region. (D) Enlarged view of the cavity region. Residues that line the cavity and are not solvent exposed are colored magenta. Residue E187 of each protomer is colored teal and shown as spheres. Fusion loops for two protomers are marked with asterisks; the third pair of fusion loops lies behind the crystal structure and is not visible. Panels B, C, and D were made by using Pymol (http://www.pymol.org/).Five other nonfunctional mutants have insertions after residues D663, T665, V667, I671, or L673, respectively. We refer to them as “hinge mutants.” These residues lie in the region located between domains IV and V, which has been termed the hinge region because it may play an important role during the conformational transition from the prefusion to the postfusion form (17). Lin and Spear proposed that insertions following these residues “would likely affect hinge regions” (21), with the implication that they may prevent gB from refolding into the postfusion conformation. Our analysis suggested that insertions after these residues could, perhaps, be sterically accommodated in the structure but would probably be energetically unfavorable by causing several buried hydrophobic side chains in the 665-673 region, such as F670, I671, and L673, to become exposed (Fig. 1B and C).In light of these observations, we hypothesized that the insertion mutants are “trapped” in a prefusion form. We decided to test this hypothesis by determining whether the ectodomain of gB containing one of these insertion mutations is able to assume the conformation seen in the crystal structure of the wild-type gB ectodomain, which we are referring to as the likely postfusion conformation. For this purpose, we chose one cavity mutant, containing an insertion after E187, and four hinge mutants, containing insertions after T665, V667, I671, or L673, respectively. We chose to test four hinge mutants because structure analysis suggested to us that insertions following the respective residues might not affect the structure in precisely the same way. We expressed the soluble ectodomain of each mutant by using a baculovirus expression system and characterized the purified proteins by using biochemical and biophysical methods. Surprisingly, we found that the ectodomains of all five mutants assume a conformation similar to that of the wild-type gB ectodomain. The four hinge mutants had biochemical properties and overall three-dimensional structures that were indistinguishable from those of the wild-type gB ectodomain. We conclude that these mutants undergo only minor local conformational changes to relieve the steric strain resulting from the presence of 5 extra amino acids. Interestingly, the cavity mutant, while able to adopt the overall postfusion structure, still displayed significant conformational differences relative to wild-type gB. Because these conformational differences are in the vicinity of fusion loops, we conclude that the fusion loops in this mutant have decreased functional activity.     

Activation of Swelling-activated Chloride Current by Tumor Necrosis Factor-α Requires ClC-3-dependent Endosomal Reactive Oxygen Production

ClC-3 is a Cl⁻/H⁺ antiporter required for cytokine-induced intraendosomal reactive oxygen species (ROS) generation by Nox1. ClC-3 current is distinct from the swelling-activated chloride current (ICl_swell), but overexpression of ClC-3 can activate currents that resemble ICl_swell. Because H₂O₂ activates ICl_swell directly, we hypothesized that ClC-3-dependent, endosomal ROS production activates ICl_swell. Whole-cell perforated patch clamp methods were used to record Cl⁻ currents in cultured aortic vascular smooth muscle cells from wild type (WT) and ClC-3 null mice. Under isotonic conditions, tumor necrosis factor-α (TNF-α) (10 ng/ml) activated outwardly rectifying Cl⁻ currents with time-dependent inactivation in WT but not ClC-3 null cells. Inhibition by tamoxifen (10 μm) and by hypertonicity (340 mosm) identified them as ICl_swell. ICl_swell was also activated by H₂O₂ (500 μm), and the effect of TNF-α was completely inhibited by polyethylene glycol-catalase. ClC-3 expression induced ICl_swell in ClC-3 null cells in the absence of swelling or TNF-α, and this effect was also blocked by catalase. ICl_swell activation by hypotonicity (240 mosm) was only partially inhibited by catalase, and the size of these currents did not differ between WT and ClC-3 null cells. Disruption of endosome trafficking with either mutant Rab5 (S34N) or Rab11 (S25N) inhibited TNF-α-mediated activation of ICl_swell. Thrombin also activates ROS production by Nox1 but not in endosomes. Thrombin caused H₂O₂-dependent activation of ICl_swell, but this effect was not ClC-3- or Rab5-dependent. Thus, activation of ICl_swell by TNF-α requires ClC-3-dependent endosomal H₂O₂ production. This demonstrates a functional link between two distinct anion currents, ClC-3 and ICl_swell.     

Characterization of the O-antigen Polymerase (Wzy) of Francisella tularensis

The O-antigen polymerase of Gram-negative bacteria has been difficult to characterize. Herein we report the biochemical and functional characterization of the protein product (Wzy) of the gene annotated as the putative O-antigen polymerase, which is located in the O-antigen biosynthetic locus of Francisella tularensis. In silico analysis (homology searching, hydropathy plotting, and codon usage assessment) strongly suggested that Wzy is an O-antigen polymerase whose function is to catalyze the addition of newly synthesized O-antigen repeating units to a glycolipid consisting of lipid A, inner core polysaccharide, and one repeating unit of the O-polysaccharide (O-PS). To characterize the function of the Wzy protein, a non-polar deletion mutant of wzy was generated by allelic replacement, and the banding pattern of O-PS was observed by immunoblot analysis of whole-cell lysates obtained by SDS-PAGE and stained with an O-PS-specific monoclonal antibody. These immunoblot analyses showed that O-PS of the wzy mutant expresses only one repeating unit of O-antigen. Further biochemical characterization of the subcellular fractions of the wzy mutant demonstrated that (as is characteristic of O-antigen polymerase mutants) the low molecular weight O-antigen accumulates in the periplasm of the mutant. Site-directed mutagenesis based on protein homology and topology, which was carried out to locate a catalytic residue of the protein, showed that modification of specific residues (Gly¹⁷⁶, Asp¹⁷⁷, Gly³²³, and Tyr³²⁴) leads to a loss of O-PS polymerization. Topology models indicate that these amino acids most likely lie in close proximity on the bacterial surface.