Sphingosine 1-Phosphate (S1P) Carrier-dependent Regulation of Endothelial Barrier: HIGH DENSITY LIPOPROTEIN (HDL)-S1P PROLONGS ENDOTHELIAL BARRIER ENHANCEMENT AS COMPARED WITH ALBUMIN-S1P VIA EFFECTS ON LEVELS,TRAFFICKING, AND SIGNALING OF S1P1*

Sphingosine 1-phosphate (S1P) is a blood-borne lysosphingolipid that acts to promote endothelial cell (EC) barrier function. In plasma, S1P is associated with both high density lipoproteins (HDL) and albumin, but it is not known whether the carriers impart different effects on S1P signaling. Here we establish that HDL-S1P sustains EC barrier longer than albumin-S1P. We showed that the sustained barrier effects of HDL-S1P are dependent on signaling by the S1P receptor, S1P1, and involve persistent activation of Akt and endothelial NOS (eNOS), as well as activity of the downstream NO target, soluble guanylate cyclase (sGC). Total S1P1 protein levels were found to be higher in response to HDL-S1P treatment as compared with albumin-S1P, and this effect was not associated with increased S1P1 mRNA or dependent on de novo protein synthesis. Several pieces of evidence indicate that long term EC barrier enhancement activity of HDL-S1P is due to specific effects on S1P1 trafficking. First, the rate of S1P1 degradation, which is proteasome-mediated, was slower in HDL-S1P-treated cells as compared with cells treated with albumin-S1P. Second, the long term barrier-promoting effects of HDL-S1P were abrogated by treatment with the recycling blocker, monensin. Finally, cell surface levels of S1P1 and levels of S1P1 in caveolin-enriched microdomains were higher after treatment with HDL-S1P as compared with albumin-S1P. Together, the findings reveal S1P carrier-specific effects on S1P1 and point to HDL as the physiological mediator of sustained S1P1-PI3K-Akt-eNOS-sGC-dependent EC barrier function.     

Stilbenoids from Tragopogon orientalis

A phytochemical investigation of Tragopogon orientalis L. (Asteraceae, Cichorieae) yielded the natural products 6'-O-(7,8-dihydrocaffeoyl)-alpha,beta-dihydrorhaponticin, 3'-O-methyl-alpha,beta-dihydrorhaponticin, and (S)-3-(4-beta-glucopyranosyloxybenzyl)-7-hydroxy-5-methoxyphtalide as well as known compounds alpha,beta-dihydrorhaponticin, 3-(4-methoxybenzyl)-5,7-dimethoxyphthalide, p-dihydrocoumaric acid methyl ester, and 1-hydroxypinoresinol-1-O-beta-glucopyranoside. The structures were established by HR mass spectrometry, extensive 1D and 2D NMR spectroscopy, and CD spectroscopy. Moreover, the radical scavenging activities of the major compounds were measured using the 2,2-diphenyl-1-picrylhydrazyl (DPPH) assay. The chemosystematic impact of the occurrence of stilbene derivatives in T. orientalis is discussed.     

Post-damage alkaloid concentration in sweet and bitter lupin varieties and its effect on subsequent herbivory

Abstract:  While most lupin species possess quinolizidine alkaloids, sweet (low alkaloid) varieties are more palatable but at the same time more susceptible to herbivory. Nevertheless, as they are not totally devoid of alkaloids, it may be possible that their alkaloid levels increase after damage. The aim of this study was to compare inductive responses to herbivory in sweet and bitter varieties of Lupinus albus (L.) and Lupinus angustifolius (L.), and to assess if these responses were effective to stop subsequent herbivory. Two experiments were carried out; in the first, Anticarsia gemmatalis (Hübner; Lep., Noctuidae) caterpillars were introduced in field-growing lupin plants and allowed to feed for 72 h, after which leaves were collected and analysed for alkaloid content and composition. The second experiment was a bioassay, in which leaves collected from experiment 1, from treated and control plants, were offered to another set of Anticarsia caterpillars, and consumption was recorded after 24 h. We found that both L. albus varieties (sweet and bitter) had an increase in their alkaloid concentration after damage, while none of the L. angustifolius varieties had. The sweet L. albus variety, Rumbo, had a greater inductive response than the bitter variety. When leaves were offered to caterpillars (bioassay), this variety showed the greatest difference between consumption of controls and previously eaten leaves, implying that alkaloid levels reached after damage were effective to deter subsequent herbivores as a result of plants probably overcoming a 'palatability threshold'.     

ZupT Is a Zn(II) Uptake System in Escherichia coli

Escherichia coli zupT (ygiE), encoding a ZIP family member, mediated zinc uptake. Growth of cells disrupted in both zupT and the znuABC operon was inhibited by EDTA at a much lower concentration than a single mutant or the wild type. Cells expressing ZupT from a plasmid exhibited increased uptake of (65)Zn(2+).     

Protection by group II phospholipase A2 against Staphylococcus aureus.

Group II phospholipase A2 (PLA2) is an enzyme that has marked antibacterial properties in vitro. To define the role of group II PLA2 in the defense against Staphylococcus aureus, we studied host responses in transgenic mice expressing human group II PLA2 and group II PLA2-deficient C57BL/6J mice in experimental S. aureus infection. After the administration of S. aureus, the transgenic mice showed increased expression of group II PLA2 mRNA in the liver and increased concentration of group II PLA2 in serum, whereas the PLA2-deficient mice completely lacked the PLA2 response. Expression of human group II PLA2 resulted in reduced mortality and improved the resistance of the mice by killing the bacteria as indicated by low numbers of live bacteria in their tissues. Human group II PLA2 was responsible for the bactericidal activity of transgenic mouse serum. These results suggest a possible role for group II PLA2 in the innate immunity against S. aureus infection.     

Guild‐specific shifts in visitation rates of frugivores with habitat loss and plant invasion

Habitat loss and plant invasions are two major drivers of global change in subtropical and tropical ecosystems. Both lead to a loss of biodiversity and alter species interactions, which may imperil vital ecosystem processes such as seed dispersal by frugivores. Reponses of frugivores to disturbance are often linked to their specialization on certain habitats or resources. Yet, it is poorly understood how habitat loss and plant invasion structure interactions between plants and different habitat or feeding guilds. Here we investigated whether visitation rates of frugivores change guild‐specifically with increasing habitat loss and invasion level in a heterogeneous subtropical landscape. In 756 h of observations, we recorded 1446 plant–frugivore interactions among 18 plant species and 42 avian frugivore species. Visitation rates of forest specialists decreased with increasing habitat loss, but not with changes in invasion level. In contrast forest generalists and forest visitors were unaffected by either driver. Similarly, obligate frugivores that overall showed a generalized fruit choice were unaffected by habitat loss and changes in invasion level. Contrary, visitation rates of specialized partial and opportunistic frugivores decreased with higher invasion level. Importantly, the negative effect of plant invasion on partial frugivores was more pronounced as habitat loss in the same study site increased, indicating a synergistic effect of the two drivers. The implications of our study are twofold: first, frugivores respond guild‐specifically to habitat loss and plant invasion. Thereby forest dependency is mainly related to habitat loss, and degree of frugivory mainly related to plant invasion. Forest generalists and obligate frugivores in turn may play a key‐role for forest regeneration in disturbed forest landscapes. Second, particularly frugivores with a specialized fruit choice may be threatened by synergistic effects between habitat loss and plant invasion.     

Structural Basis for the Differential Binding Affinities of the HsfBD1 and HsfBD2 Domains in the Haemophilus influenzae Hsf Adhesin

Haemophilus influenzae is a human-specific gram-negative coccobacillus that causes a variety of human infections ranging from localized respiratory infections to invasive diseases. Hsf is the major nonpilus adhesin in encapsulated strains of H. influenzae and belongs to the trimeric autotransporter family of proteins. The Hsf protein contains two highly homologous binding domains, designated HsfBD1 and HsfBD2. In this study we characterized the differential binding properties of HsfBD1 and HsfBD2. In assays using HeLa cells, we found that bacteria expressing either full-length Hsf or HsfBD1 by itself adhered at high levels, while bacteria expressing HsfBD2 by itself adhered at low levels. Immunofluorescence microscopy and a cellular enzyme-linked immunosorbent assay using purified proteins revealed that the binding affinity was significantly higher for HsfBD1 than for HsfBD2. Purified HsfBD1 was able to completely block adherence by bacteria expressing either HsfBD1 or HsfBD2, while purified HsfBD2 was able to block adherence by bacteria expressing HsfBD2 but had minimal activity against bacteria expressing HsfBD1. Conversion of the residue at position 1935 in the HsfBD1 binding pocket from Asp to Glu resulted in HsfBD2-like binding properties, and conversion of the residue at position 569 in the HsfBD2 binding pocket from Glu to Asp resulted in HsfBD1-like binding properties, as assessed by adherence assays with recombinant bacteria and by immunofluorescence microscopy with purified proteins. This work demonstrates the critical role of a single amino acid in the core of the binding pocket in determining the relative affinities of the HsfBD1 and HsfBD2 binding domains.Haemophilus influenzae is a gram-negative coccobacillus that causes both serious invasive diseases and localized respiratory tract infections in humans (10, 17, 19). Isolates of H. influenzae can be separated into encapsulated and nonencapsulated or so-called nontypeable strains (12). Most strains recovered from patients with invasive disease are encapsulated and express the type b capsule, while the majority of strains associated with respiratory tract infections are nontypeable (19).The pathogenesis of disease due to H. influenzae type b begins with colonization of the upper respiratory tract (4, 8, 11, 13, 16, 19). Most type b strains are capable of expressing hemagglutinating pili, which mediate bacterial attachment to oropharyngeal epithelial cells, extracellular matrix proteins, and mucin and promote colonization. Mutant strains that lack hemagglutinating pili are also capable of adherence and colonization, highlighting the fact that nonpilus adhesive factors also exist (4, 5, 8, 20). In recent work, we have demonstrated that the major nonpilus adhesin in H. influenzae type b is a large protein called Hsf, which forms short fibers visible by electron microscopy (15).The Hsf adhesin is encoded by the hsf locus and is a trimeric autotransporter protein that shares significant homology with Hia, a trimeric autotransporter adhesin that is present in ∼25% of nontypeable H. influenzae strains. Hsf contains an N-terminal signal sequence, an internal passenger domain with two binding domains, and a C-terminal outer membrane pore-forming domain, analogous to Hia (3, 6). The binding domains in Hsf are called HsfBD1 and HsfBD2 and share high-level homology with each other and with the two binding domains in Hia (2, 14). HsfBD1 and HsfBD2 interact with the same host cell receptor structure on Chang epithelial cells, although with different affinities (3). Based on in vitro experiments using purified proteins and Chang epithelial cells, HsfBD1 has a dissociation constant (K_d) of ∼0.2 nM and HsfBD2 has a K_d of ∼2.5 nM.In previous work using X-ray crystallography and site-directed mutagenesis, we established that both HiaBD1 and HiaBD2 are trimeric structures with acidic binding pockets formed by contiguous IsNeck and Trp-ring domains (9, 21). Using structural modeling and site-directed mutagenesis, we determined that HsfBD1 and HsfBD2 possess the same fold and trimeric assembly as HiaBD1 and HiaBD2, with conservation of the residues that are essential for HiaBD1 adhesive activity (3).In the current study we examined the structural basis for the different binding affinities of HsfBD1 and HsfBD2. In initial experiments, we found that the differences between HsfBD1 and HsfBD2 were easier to observe with HeLa cells than with Chang cells, reflecting the fact that the receptor density is lower on HeLa cells. Our results demonstrated the critical role of a single amino acid in the core of the binding pocket in determining the relative affinities of HsfBD1 and HsfBD2.     

Class I α-Mannosidases Are Required for N-Glycan Processing and Root Development in Arabidopsis thaliana

In eukaryotes, class I α-mannosidases are involved in early N-glycan processing reactions and in N-glycan–dependent quality control in the endoplasmic reticulum (ER). To investigate the role of these enzymes in plants, we identified the ER-type α-mannosidase I (MNS3) and the two Golgi-α-mannosidase I proteins (MNS1 and MNS2) from Arabidopsis thaliana. All three MNS proteins were found to localize in punctate mobile structures reminiscent of Golgi bodies. Recombinant forms of the MNS proteins were able to process oligomannosidic N-glycans. While MNS3 efficiently cleaved off one selected α1,2-mannose residue from Man₉GlcNAc₂, MNS1/2 readily removed three α1,2-mannose residues from Man₈GlcNAc₂. Mutation in the MNS genes resulted in the formation of aberrant N-glycans in the mns3 single mutant and Man₈GlcNAc₂ accumulation in the mns1 mns2 double mutant. N-glycan analysis in the mns triple mutant revealed the almost exclusive presence of Man₉GlcNAc₂, demonstrating that these three MNS proteins play a key role in N-glycan processing. The mns triple mutants displayed short, radially swollen roots and altered cell walls. Pharmacological inhibition of class I α-mannosidases in wild-type seedlings resulted in a similar root phenotype. These findings show that class I α-mannosidases are essential for early N-glycan processing and play a role in root development and cell wall biosynthesis in Arabidopsis.N-glycosylation is a major co- and posttranslational modification of proteins in eukaryotic cells. The biosynthesis of protein N-linked glycans starts in the endoplasmic reticulum (ER) when the oligosaccharyltransferase complex catalyzes the transfer of the Glc₃Man₉GlcNAc₂ oligosaccharide from the lipid-linked precursor to Asn residues (N-X-S/T) of nascent polypeptide chains. Subsequent N-glycan processing involves a series of highly coordinated step-by-step enzymatic conversions occurring in the ER and Golgi apparatus (Kornfeld and Kornfeld, 1985). In the first trimming reactions, α-glucosidases I (GCSI) and GCSII cleave off three glucose residues from Glc₃Man₉GlcNAc₂ to generate Man₉GlcNAc₂ (Figure 1A). The next steps of the pathway are the removal of four α1,2-linked mannose residues to provide the Man₅GlcNAc₂ substrate for the formation of complex N-glycans in the Golgi apparatus. In mammals, these mannose trimming reactions are catalyzed by class I α-mannosidases (glycosyl hydrolase family 47 of the Carbohydrate Active Enzymes database; http://www.cazy.org/). These enzymes are inverting glycosyl hydrolases that are highly specific for α1,2-mannose residues, require Ca²⁺ for catalytic activity, and are sensitive to inhibition by pyranose analogs such as 1-deoxymannojirimycin and kifunensine (Lipari et al., 1995; Gonzalez et al., 1999). Class I α-mannosidases are conserved through eukaryotic evolution and do not share sequence homology with class II α-mannosidases, such as Golgi α-mannosidase II and the catabolic lysosomal and cytoplasmic α-mannosidases (Gonzalez et al., 1999; Herscovics, 2001).Open in a separate windowFigure 1.Cartoon of Important Oligosaccharide Structures.(A) Man₉GlcNAc₂ oligosaccharide (Man9): the substrate for ER-MNSI.(B) Man₈GlcNAc₂ isomer Man8.1 according to Tomiya et al. (1991): the product of ER-MNSI and substrate for Golgi-MNSI.(C) Man₅GlcNAc₂ (Man5.1): the product of the mannose trimming reactions.The linkage of the sugar residues is indicated.[See online article for color version of this figure.]The mammalian class I α-mannosidase family consists of three protein subgroups, which have been distinguished based on their sequence similarity and proposed function: ER-α1,2-mannosidases I (ER-MNSIs), Golgi-α-mannosidases I (Golgi-MNSIs), and ER degradation-enhancing α-mannosidase (EDEM)-like proteins (Mast and Moremen, 2006). In humans, there is a single ER-MNSI, which cleaves the terminal mannose residue from the b-branch of the Man₉GlcNAc₂ oligosaccharide to create the Man₈GlcNAc₂ isomer Man8.1 (Figure 1B). Subsequently, Golgi-MNSI (three isoforms, Golgi-MNSIA, Golgi-MNSIB, and Golgi-MNSIC, are present in humans) catalyze the removal of the remaining three α1,2-linked mannose residues to generate Man₅GlcNAc₂ (Figure 1C). The three human EDEM proteins are not directly involved in N-glycan processing but play a role in ER-associated degradation of glycoproteins (Mast et al., 2005; Hirao et al., 2006; Olivari et al., 2006).The formation of the Man₈GlcNAc₂ isomer (Man8.1), which is catalyzed by ER-MNSI, is the last N-glycan processing step that is conserved in yeast and mammals. Apart from its N-glycan processing function, ER-MNSI plays a key role in ER-mediated quality control of glycoproteins in yeasts and mammals (Mast and Moremen, 2006; Lederkremer, 2009). It has been proposed that ER-MNSI cooperates with mammalian EDEM1 to 3 or the yeast α1,2-mannosidase HTM1 to generate the signal that marks misfolded glycoproteins for degradation through the ER-associated protein degradation (ERAD) pathway. This quality control process, which finally leads to retrotranslocation to the cytoplasm and hydrolysis by the 26S proteasome, serves to prevent the secretion of aberrantly folded cargo proteins and is required to maintain protein homeostasis in the ER. Initially it was proposed that the Man₈GlcNAc₂ isomer Man8.1 (Figure 1B) flags aberrantly folded glycoproteins for degradation; however, recent evidence suggests that further mannose trimming to Man₇GlcNAc₂ in yeast and Man_5-6GlcNAc₂ in mammals is required to trigger ERAD (Avezov et al., 2008; Clerc et al., 2009). In addition, these mannose cleavage reactions serve also to release glycoproteins from the calnexin/calreticulin quality control cycle (Caramelo and Parodi, 2008).Unlike for animals and yeast, much less is known about the biological function of plant class I α-mannosidases. Processing mannosidases have been purified and characterized from mung bean (Vigna radiata) seedlings and castor bean (Ricinus communis) cotyledons (Forsee, 1985; Szumilo et al., 1986; Kimura et al., 1991). These preparations were a mixture of different α-mannosidases, and no evidence for ER-MNSI-like activity was provided. A putative Golgi-α-mannosidase I has been cloned from soybean (Glycine max) (Nebenführ et al., 1999). A green fluorescent protein (GFP)-tagged fusion protein of the soybean enzyme has been shown to reside in the cis-stacks of the Golgi apparatus (Nebenführ et al., 1999; Saint-Jore-Dupas et al., 2006), but its role in N-glycan processing and its enzymatic properties have not been reported so far. Thus, the involvement of class I α-mannosidases in N-glycan processing as well as in glycoprotein quality control in plants is still unclear, and the existence of a plant ER-MNSI has so far been inferred only from the presence of Man₈GlcNAc₂ oligosaccharides on ER-resident glycoproteins (Pagny et al., 2000).Here, we report the molecular cloning and biochemical characterization of the enzymes accounting for ER-MNSI and Golgi-MNSI activities in Arabidopsis thaliana. We also demonstrate that disruption of these genes leads to severe cell expansion defects in roots as well as to distinct cell wall alterations. Hence, the identification of the Arabidopsis ER-type and Golgi class I α-mannosidases not only establishes the molecular basis for the missing steps in the plant N-glycan processing pathway but also provides unprecedented insights into the role of N-glycans in plant development.