Bioactivity of secoiridoid glycosides from Centaurium erythraea.

As part of our on-going search for bioactive compounds from Scottish plants, two secoiridoid glycosides, swertiamarin and sweroside, have been isolated from the aerial parts of Centaurium erythraea Rafn (Family: Gentianaceae) by reversed-phase preparative HPLC coupled with a photo-diode-array detector. The structures of these compounds were elucidated unambiguously by UV, FABMS and extensive 1D and 2D NMR spectroscopic analyses and also by comparing experimental data with literature data. Antibacterial, free radical scavenging activities and general toxicity of these glycosides have been assessed. Both compounds inhibited the growth of Bacillus cereus, Bacillus subtilis, Citrobacter freundii and Escherichia coli. While swertiamarin was also active against Proteus mirabilis and Serratia marcescens, sweroside inhibited the growth of Staphylococcus epidermidis. Swertiamarin and sweroside exhibited significant general toxicity in brine shrimp lethality bioassay and the LD50 values were 8.0 microg/ml and 34 microg/ml, respectively, whereas that of the positive control podophyllotoxin, a well known cytotoxic lignan, was 2.79 microg/ml. Chemotaxonomic implications of these compounds in the family Gentianaceae have also been discussed briefly.     

Neuroadaptations in the Striatal Proteome of the Rat Following Prolonged Excessive Sucrose Intake

Obesity is a contemporary health problem of rapidly increasing prevalence. One possible cause of obesity is loss of control over consumption of highly palatable foodstuffs, perhaps mirroring the processes involved in drug addiction. Accordingly, the striatum may be a key neural substrate involved in both food and drug craving. We hypothesised here that prolonged exposure to 10 % sucrose solution might cause neuroadaptations in the striatum that are analogous to those previously reported following prolonged exposure to alcohol or recreational drugs. Male Wistar rats were given constant access to 10 % sucrose solution (in addition to normal lab chow and tap water) for 8 months and were compared with control rats receiving no sucrose access. Rats in the sucrose group typically drank more than 100 ml of sucrose solution per day and showed 13 % greater body weight than controls at the end of the 8 months. Striatal dopamine (DA) concentrations were decreased in the sucrose group rats relative to controls. Differential expression of 18 proteins was identified in the striatum of the sucrose group rats relative to controls. Down regulated proteins included pyridoxal phosphate phosphatase, involved in DA synthesis, and glutathione transferase, involved in free radical scavenging. Up regulated proteins included prolactin (which is under negative regulation by DA) and adipose differentiation-related protein, involved in fat synthesis. We hypothesise that DA-related neuroadaptations in the striatum caused by prolonged sucrose intake may partly drive compulsive intake and seeking of high palatability foodstuffs, in a similar way to that observed with drug and alcohol addictions.     

Cell-Autonomous Progeroid Changes in Conditional Mouse Models for Repair Endonuclease XPG Deficiency

As part of the Nucleotide Excision Repair (NER) process, the endonuclease XPG is involved in repair of helix-distorting DNA lesions, but the protein has also been implicated in several other DNA repair systems, complicating genotype-phenotype relationship in XPG patients. Defects in XPG can cause either the cancer-prone condition xeroderma pigmentosum (XP) alone, or XP combined with the severe neurodevelopmental disorder Cockayne Syndrome (CS), or the infantile lethal cerebro-oculo-facio-skeletal (COFS) syndrome, characterized by dramatic growth failure, progressive neurodevelopmental abnormalities and greatly reduced life expectancy. Here, we present a novel (conditional) Xpg^−/− mouse model which -in a C57BL6/FVB F1 hybrid genetic background- displays many progeroid features, including cessation of growth, loss of subcutaneous fat, kyphosis, osteoporosis, retinal photoreceptor loss, liver aging, extensive neurodegeneration, and a short lifespan of 4–5 months. We show that deletion of XPG specifically in the liver reproduces the progeroid features in the liver, yet abolishes the effect on growth or lifespan. In addition, specific XPG deletion in neurons and glia of the forebrain creates a progressive neurodegenerative phenotype that shows many characteristics of human XPG deficiency. Our findings therefore exclude that both the liver as well as the neurological phenotype are a secondary consequence of derailment in other cell types, organs or tissues (e.g. vascular abnormalities) and support a cell-autonomous origin caused by the DNA repair defect itself. In addition they allow the dissection of the complex aging process in tissue- and cell-type-specific components. Moreover, our data highlight the critical importance of genetic background in mouse aging studies, establish the Xpg^−/− mouse as a valid model for the severe form of human XPG patients and segmental accelerated aging, and strengthen the link between DNA damage and aging.     

Structural Characterization of a Gcn5-Related N-Acetyltransferase from Staphylococcus aureus

The Gcn5-related N-acetyltransferases (GNATs) are ubiquitously expressed in nature and perform a diverse range of cellular functions through the acetylation of small molecules and protein substrates. Using activated acetyl coenzyme A as a common acetyl donor, GNATs catalyse the transfer of an acetyl group to acceptor molecules including aminoglycoside antibiotics, glucosamine-6-phosphate, histones, serotonin and spermidine. There is often only very limited sequence conservation between members of the GNAT superfamily, in part, reflecting their capacity to bind a diverse array of substrates. In contrast, the secondary and tertiary structures are highly conserved, but then at the quaternary level there is further diversity, with GNATs shown to exist in monomeric, dimeric, or tetrameric states. Here we describe the X-ray crystallographic structure of a GNAT enzyme from Staphyloccocus aureus with only low sequence identity to previously solved GNAT proteins. It contains many of the classical GNAT motifs, but lacks other hallmarks of the GNAT fold including the classic β-bulge splayed at the β-sheet interface. The protein is likely to be a dimer in solution based on analysis of the asymmetric unit within the crystal structure, homology with related GNAT family members, and size exclusion chromatography. The study provides the first high resolution structure of this enzyme, providing a strong platform for substrate and cofactor modelling, and structural/functional comparisons within this diverse enzyme superfamily.     

A unified framework for the restoration of Southeast Asian mangroves—bridging ecology, society and economics

The effect of intensive human intervention, poor socio-economic conditions and little knowledge on mangrove ecology pose enormous challenges for mangrove restoration in Southeast Asia. We present a framework for tropical mangrove restoration. Our proposed restoration framework addresses the ecology, economy and social issues simultaneously by considering the causes of mangrove degradation. We provide a step by step guideline for its restoration. We argue that although, ecological issues are of prime importance, economic and social issues must be considered in the restoration plan in order for it to be successful. Since mangrove ecology is not adequately studied in this region, local ecological knowledge can be used to fill the baseline information gaps. Unwanted human disturbance can be minimized by encouraging community participation. This can be ensured and sustained by facilitating the livelihood of the coastal community. We translated the restoration paradigm into a readily available practical guideline for the executors of the plans. We provide an example of mangrove restoration project that is closely related to our proposed framework. We are optimistic that this framework has the potential for universal application with necessary adjustments.     

The Processing of a 57-kDa Precursor Peptide to Subunits of Rice Glutelin

The processing of a 57-kDa peptide into 37- and 22-kDa subunitsof glutelin, a major storage protein of rice, was confirmedby the immunological compatibility between the precursor andglutelin subunits. The 57-kDa peptide reacted with the antiseraraised against purified 37-kDa and 22-kDa subunits of glutelin.The processing was further confirmed by alteration of an invivo protein synthesis by monensin, a sodium ionophore whichinhibits the intracellular transport of secretory and membraneproteins. Infusion of monensin into developing rice grains resultedin suppressed formation of mature glutelin subunits with concomitantaccumulation of the 57-kDa peptide. The present results indicatethat both subunits of rice glutelin were produced by post-translationalcleavage of the 57-kDa peptide. (Received July 9, 1986; Accepted October 1, 1986)     

Docking of human rhodopsin mutant (Gly90→Asp) with beta-arrestin and cyanidin 3-rutinoside to cure night blindness

MOTIVATION: Rhodopsin is a visual pigment present in rod cells of retina. It belongs to GPCR family and involves photoisomerization of 11-cis-retinal to all-trans-retinal isomers, conformational changes in rhodopsin and signal transduction cascade to generate a nerve impulse. This signaling pathway has been targeted to eliminate the effect of a mutation (Gly90→Asp) responsible for abnormal activation of G-protein without retinal conformations in the absence of light leading to congenital night blindness. A theoretical model of rhodopsin with induced mutation has been deliberated in order to find potential ligands which can offset this mutational effect. The binding interactions between the target mutated rhodopsin model and potential ligands have been predicted with the help of molecular docking. The results indicated strong functional benefits of ligands as an inhibitor and an agonist for mutated rhodopsin model. Therefore, we propose a new visual cascade model which can initiate the normal signaling of rhodopsin mutant with the help of proposed ligands and can provide a hope for vision in future.     

β2-Adrenergic receptor polymorphisms: pharmacogenetic response to bronchodilator among African American asthmatics

Beta2-adrenergic receptor (beta2AR) gene polymorphisms have been reported to be associated with various asthma-related traits in different racial/ethnic populations. However, it is unknown whether beta2AR genetic variants are associated with asthma in African Americans. In this study, we have examined whether there is association between beta2AR genetic variants and asthma in African Americans. We have recruited 264 African American asthmatic subjects and 176 matched healthy controls participating in the Study of African Americans, Asthma, Genes and Environments (SAGE). We genotyped seven known and recently identified beta2AR SNP variants, then tested genotype and haplotype association of asthma-related traits with the beta2AR SNPs in our African American cohort with adjustment of confounding effect due to admixture background and environmental risk factors. We found a significant association of the SNP -47 (Arg-19Cys) polymorphism with DeltaFEF(25-75), a measure of bronchodilator drug responsiveness, in African American asthmatics after correction for multiple testing (P = 0.001). We did not observe association of the SNP +46 (Arg16Gly) variant with asthma disease diagnosis and asthma-related phenotypes. In contrast to previous results between the Arg16Gly variant and traits related to bronchodilator responsiveness, our results indicate that the Arg-19Cys polymorphism in beta upstream peptide may play an important role in bronchodilator drug responsiveness in African American subjects. Our findings highlight the importance of investigating genetic risk factors for asthma in different populations.     

Role of GerKB in Germination and Outgrowth of Clostridium perfringens Spores

Previous work indicated that Clostridium perfringens gerKA gerKC spores germinate significantly, suggesting that gerKB also has a role in C. perfringens spore germination. We now find that (i) gerKB was expressed only during sporulation, likely in the forespore; (ii) gerKB spores germinated like wild-type spores with nonnutrient germinants and with high concentrations of nutrients but more slowly with low nutrient concentrations; and (iii) gerKB spores had lower colony-forming efficiency and slower outgrowth than wild-type spores. These results suggest that GerKB plays an auxiliary role in spore germination under some conditions and is required for normal spore viability and outgrowth.Spores of Bacillus and Clostridium species can break dormancy upon sensing a variety of compounds (termed germinants), including amino acids, nutrient mixtures, a 1:1 chelate of Ca²⁺ and pyridine-2,6-dicarboxylic acid (dipicolinic acid [DPA]), and cationic surfactants such as dodecylamine (20). Nutrient germinants are sensed by their cognate receptors, located in the spore''s inner membrane (6), which are composed of proteins belonging to the GerA family (10, 11). In Bacillus subtilis, three tricistronic operons (gerA, gerB, and gerK) expressed uniquely during sporulation in the developing forespore each encode the three major germinant receptors, with different receptors responding to a different spectrum of nutrient germinants (5, 9, 20). Null mutations in any cistron in a gerA family operon inactivate the function of the respective receptor (9, 11). In contrast, Clostridium perfringens, a gram-positive, spore-forming, anaerobic pathogenic bacterium, has no tricistronic gerA-like operon but only a monocistronic gerAA that is far from a gerK locus. This locus contains a bicistronic gerKA-gerKC operon and a monocistronic gerKB upstream of and in the opposite orientation to gerKA-gerKC (Fig. ​(Fig.1A)1A) (16). GerAA has an auxiliary role in the germination of C. perfringens spores at low germinant concentrations, while GerKA and/or GerKC are required for l-asparagine germination and have partial roles in germination with KCl and a mixture of KCl and l-asparagine (AK) (16). In contrast to the situation with B. subtilis, where germinant receptors play no role in Ca-DPA germination (12, 13), GerKA and/or GerKC is required for Ca-DPA germination (16). The partial requirement for GerKA and/or GerKC in C. perfringens spore germination by KCl and AK suggests that the upstream gene product, GerKB, might also have some role in KCl and AK germination of C. perfringens spores. Therefore, in this study we have investigated the role of GerKB in the germination and outgrowth of C. perfringens spores.Open in a separate windowFIG. 1.Arrangement and expression of gerKB in C. perfringens SM101. (A) The arrangement of the gerK locus in C. perfringens SM101 is shown, and the locations of the primers used to amplify the upstream regions of the gerKB gene and the putative promoters of gerKB and gerKA are indicated. The gerKB promoter was predicted to be within the intergenic regions between gerKB and the gerK operon. (B) GUS specific activities from the gerKB-gusA fusion in strain SM101(pDP84) grown in TGY vegetative (filled squares) and DS sporulation (open squares) media were determined as described in the text. Data represent averages from three independent experiments with the error bars representing standard deviations, and time zero denotes the time of inoculation of cells into either TGY or DS medium.To determine if gerKB is expressed during sporulation, 485 bp upstream of the gerKB coding sequence, including DNA between gerKB and gerKA, was PCR amplified with primer pair CPP389/CPP391, which had SalI and PstI cleavage sites, respectively (see Table S2 in the supplemental material). The PCR fragment was cloned between SalI and PstI cleavage sites in plasmid pMRS127 (17) to create a gerKB-gusA fusion in plasmid pDP84 (see Table S1 in the supplemental material). This plasmid was introduced into C. perfringens SM101 by electroporation (3), and Em^r transformants were selected. The SM101 transformant carrying plasmid pDP84 was grown in TGY vegetative growth medium (3% Trypticase soy, 2% glucose, 1% yeast extract, 0.1% l-cysteine) (7) and in Duncan-Strong (DS) (4) sporulation medium and assayed for β-glucuronidase (GUS) activity as described previously (23). Vegetative cultures of strain SM101 carrying plasmid pMRS127 (empty vector) or pDP84 (gerKB-gusA) exhibited no significant GUS activity, and strain SM101 grown in DS medium also exhibited no significant GUS activity (Fig. ​(Fig.1B1B and data not shown). However, GUS activity was observed in sporulating cultures of SM101(pDP84) (Fig. ​(Fig.1B),1B), indicating that a sporulation-specific promoter is located upstream of gerKB. The expression of the gerKB-gusA fusion began ∼3 h after induction of sporulation and reached a maximum after ∼6 h of sporulation (Fig. ​(Fig.1B).1B). The decrease in GUS activity observed after ∼6 h is consistent with the GerKB-GusA protein being packaged into the dormant spore where it cannot be easily assayed and thus with gerKB being expressed in the forespore compartment of the sporulating cell (8). These results confirm that, as with the gerKA-gerKC operon (16), gerKB is also expressed only during sporulation.To investigate the role of GerKB in C. perfringens spore germination, we constructed a gerKB mutant strain (DPS108) as described previously (14-16). A 2,203-bp DNA fragment carrying 2,080 bp upstream of and 123 bp from the N-terminal coding region of gerKB was PCR amplified using primers CPP369 and CPP367, which had XhoI and BamHI cleavage sites at the 5′ ends of the forward and reverse primers, respectively (see Table S2 in the supplemental material). A 1,329-bp fragment carrying 134 bp from the C-terminal and 1,195 bp downstream of the coding region of gerKB was PCR amplified using primers CPP371 and CPP370, which had BamHI and KpnI cleavage sites at the 5′ ends of the forward and reverse primers, respectively (see Table S2 in the supplemental material). These PCR fragments were cloned into plasmid pCR-XL-TOPO, giving plasmids pDP67 and pDP69, respectively (see Table S1 in the supplemental material). An ∼2.2-kb BamHI-XhoI fragment from pDP67 was cloned into pDP1 (pCR-XL-TOPO carrying an internal fragment of gerAA), giving plasmid pDP68, and an ∼1.4-kb KpnI-BamHI fragment from pDP69 was cloned in pDP68, giving pDP73 (see Table S1 in the supplemental material). The latter plasmid was digested with BamHI, the ends were filled, and an ∼1.3-kb NaeI-SmaI fragment carrying catP from pJIR418 (1) was inserted, giving plasmid pDP74. Finally, an ∼4.8-kb KpnI-XhoI fragment from pDP74 (see Table S1 in the supplemental material) was cloned between the KpnI and SalI sites of pMRS104, giving pDP75, which cannot replicate in C. perfringens. Plasmid pDP75 was introduced into C. perfringens SM101 by electroporation (3), and the gerKB deletion strain DPS108 was isolated as described previously (18). The presence of the gerKB deletion in strain DPS108 was confirmed by PCR and Southern blot analyses (data not shown). Strain DPS108 gave ∼70% sporulating cells in DS sporulation medium, similar to results with the wild-type strain, SM101 (data not shown).Having obtained evidence for successful construction of the gerKB mutant, we compared the germinations of heat-activated (80°C; 10 min) gerKB and wild-type spores as previously described (16). Both the gerKB and wild-type spores germinated identically and nearly completely in 60 min at 40°C in brain heart infusion (BHI) broth as determined by the fall in optical density at 600 nm (OD₆₀₀) of germinating cultures and phase-contrast microscopy (data not shown). This result suggests that GerKB plays no essential role in spore germination in rich medium. The role of GerKB in C. perfringens spore germination was also assessed with individual germinants identified previously (16). Heat-activated wild-type and gerKB spores germinated similarly with high (100 mM) concentrations of KCl, l-asparagine, and AK, all in 25 mM sodium phosphate (pH 7.0), and in 50 mM Ca-DPA adjusted to pH 8.0 with Tris base (Fig. 2A to D). These results were also confirmed by phase-contrast microscopy (data not shown). However, with lower (10 to 20 mM) concentrations of KCl, l-asparagine, and AK, gerKB spore germination was very slightly (Fig. ​(Fig.2A)2A) to significantly (Fig. 2B and C) slower than that of wild-type spores. These results suggest that while GerKB is not essential for germination with high concentrations of KCl, l-asparagine, or AK, it plays a significant role in germination with low l-asparagine and AK concentrations and, further, that GerKB is not required for Ca-DPA germination. This latter finding is similar to the situation with B. subtilis spores where germinant receptors play no role in Ca-DPA germination (19, 20). However, in C. perfringens spores, GerKA and/or GerKC do play a significant role in Ca-DPA germination (16).Open in a separate windowFIG. 2.Germination of spores of C. perfringens strains with various germinants. Heat-activated spores of strains SM101 (wild type) (filled symbols) and DPS108 (gerKB) (open symbols) were incubated at an OD₆₀₀ of 1 at 40°C with high (squares) and low (triangles) germinant concentrations of 100 and 10 mM KCl (A), 100 and 20 mM l-asparagine (B), 100 and 10 mM AK (C), and 50 mM Ca-DPA (D) as described in the text, and at various times the OD₆₀₀ was measured. No significant germination was observed when heat-activated spores of SM101 and DPS108 were incubated for 60 min at 40°C in 25 mM sodium phosphate buffer (pH 7.0) (data not shown). The data shown are averages from duplicate determinations with two different spore preparations, and error bars represent standard deviations.Bacterial spores can also germinate with dodecylamine, a cationic surfactant (19). In B. subtilis spores, dodecylamine induces germination most likely by opening channels composed, at least in part, of SpoVA proteins (22), allowing release of the spores'' Ca-DPA (19). Spores of B. subtilis lacking all three functional germinant receptors release DPA, as do wild-type spores, upon incubation with dodecylamine (19), while C. perfringens spores lacking GerKA-GerKC incubated with dodecylamine release DPA slower than wild-type spores (16). However, when C. perfringens gerKB spores at an OD₆₀₀ of 1.5 were incubated with 1 mM dodecylamine in Tris-HCl (pH 7.4) at 60°C (2, 16), gerKB spores released their DPA slightly faster than wild-type spores (Fig. ​(Fig.3)3) when DPA release was measured as described previously (16). These results suggest that GerKB has no role in dodecylamine germination.Open in a separate windowFIG. 3.Germination of spores of C. perfringens strains with dodecylamine. Spores of strains SM101 (wild type) (filled squares) and DPS108 (gerKB) (open squares) were germinated with dodecylamine, and germination was monitored by measuring DPA release as described in the text. There was no significant DPA release in 60 min by spores incubated similarly but without dodecylamine (data not shown). Error bars represent standard deviations.Previous work (16) found that C. perfringens spores lacking GerKA-GerKC had lower viability than wild-type spores on rich medium plates, and it was thus of interest to determine gerKB spore viability, which was measured as previously described (14, 16). Strikingly, the colony-forming ability of gerKB spores was ∼7-fold lower (P < 0.01) than that of wild-type spores after 24 h on BHI plates (Table ​(Table1),1), and no additional colonies appeared when plates were incubated for up to 3 days (data not shown). The colony-forming ability of spores lacking GerKA and GerKC determined in parallel was ∼12-fold lower than that of wild-type spores (Table ​(Table1).1). Phase-contrast microscopy of C. perfringens spores incubated in BHI broth for 24 h under aerobic conditions to prevent vegetative cell growth indicated that >90% of wild-type spores not only had germinated but had also released the nascent vegetative cell, while >85% of gerKA gerKC and gerKB spores remained as only phase-dark germinated spores with no evidence of nascent cell release (data not shown), as found previously with gerKA gerKC spores (16). The fact that >85% of gerKB spores germinated in BHI medium in 24 h but most of these germinated spores did not progress further in development strongly suggests that GerKB is needed for normal spore outgrowth (and see below) as well as for normal spore germination.

TABLE 1.

Colony formation by spores of C. perfringens strains^a