Identification of arylsulfonamides as Aquaporin 4 inhibitors

Carbonic anhydrase inhibitors AZA, EZA, and 4-acetamidobenzsulfonamide were found to inhibit human AQP4-M23 mediated water transport by 80%, 68%, and 23%, respectively, at 20 microM in an in vitro functional assay. AZA was found to have an IC50 against AQP4 of 0.9 microM. Phloretin was inactive under the same conditions.     

Crystals of the NC1 domain of human type IV collagen

Crystals of the non-collagenous C-terminal region (NC1) of type IV collagen have been obtained from human placenta. These crystals diffract to 2.0 A, and belong to space group P22(1)2(1), with cell dimensions a = 81 A, b = 158 A, c = 138 A, alpha = beta = gamma = 90 degrees. The crystals contain one hexamer in the asymmetric unit; they are very stable with respect to X-rays.     

γδT Cells Are Prevalent in the Proximal Aorta and Drive Nascent Atherosclerotic Lesion Progression and Neutrophilia in Hypercholesterolemic Mice

Unique innate immunity-linked γδT cells have been seen in early human artery lesions, but their role in lesion development has received little attention. Here we investigated whether γδT cells modulate atherogenesis in apolipoprotein E-deficient (ApoE KO) mice. We found that γδT cell numbers were markedly increased in the proximal aorta of ApoE-deficient vs. wild-type mice during early atherogenesis, particularly in the aortic root and arch, where they comprised most of the T cells and lesion progression is most rapid. γδT cells infiltrated intimal lesions in ApoE KO mice, but only the adventitia in wild-type mice, and were more prevalent than CD4⁺ T cells in early nascent lesions, as evaluated by en face confocal microscopy. These aortic γδT cells produced IL-17, but not IFN-γ, analyzed by ex vivo FACS. Furthermore, aortic arch lipid accumulation correlated strongly with abundance of IL-17-expressing splenic γδT cells in individual ApoE KO mice. To investigate the role of these γδT cells in early atherogenesis, we analyzed ApoE/γδT double knockout (DKO) compared to ApoE KO mice. We observed reduced early intimal lipid accumulation at sites of nascent lesion formation, both in chow-fed (by 40%) and Western diet-fed (by 44%) ApoE/γδT DKO mice. In addition, circulating neutrophils were drastically reduced in these DKO mice on Western diet, while expansion of inflammatory monocytes and splenic Th1 or Th17 lymphocytes was not affected. These data reveal, for the first time, a pathogenic role of γδT cells in early atherogenesis in ApoE KO mice, by mechanisms likely to involve their IL-17 production and induction of neutrophilia. Targeting γδT cells thus might offer therapeutic benefit in atherosclerosis or other inflammatory vascular diseases.     

Crystal structures of MMP-9 complexes with five inhibitors: contribution of the flexible Arg424 side-chain to selectivity

Human matrix metalloproteinase 9 (MMP-9), also called gelatinase B, is particularly involved in inflammatory processes, bone remodelling and wound healing, but is also implicated in pathological processes such as rheumatoid arthritis, atherosclerosis, tumour growth, and metastasis. We have prepared the inactive E402Q mutant of the truncated catalytic domain of human MMP-9 and co-crystallized it with active site-directed synthetic inhibitors of different binding types. Here, we present the X-ray structures of five MMP-9 complexes with gelatinase-specific, tight binding inhibitors: a phosphinic acid (AM-409), a pyrimidine-2,4,6-trione (RO-206-0222), two carboxylate (An-1 and MJ-24), and a trifluoromethyl hydroxamic acid inhibitor (MS-560). These compounds bind by making a compromise between optimal coordination of the catalytic zinc, favourable hydrogen bond formation in the active-site cleft, and accommodation of their large hydrophobic P1' groups in the slightly flexible S1' cavity, which exhibits distinct rotational conformations of the Pro421 carbonyl group in each complex. In all these structures, the side-chain of Arg424 located at the bottom of the S1' cavity is not defined in the electron density beyond C(gamma), indicating its mobility. However, we suggest that the mobile Arg424 side-chain partially blocks the S1' cavity, which might explain the weaker binding of most inhibitors with a long P1' side-chain for MMP-9 compared with the closely related MMP-2 (gelatinase A), which exhibits a short threonine side-chain at the equivalent position. These novel structural details should facilitate the design of more selective MMP-9 inhibitors.     

Mortality event in freshwater drum Aplodinotus grunniens from Lake Ontario, Canada, associated with viral haemorrhagic septicemia virus, type IV

A mortality event primarily affecting freshwater drum Aplodinotus grunniens was noted during April and May 2005 in the Bay of Quinte, Lake Ontario, Canada. A conservative estimate of the number of dead drum was approximately 100 metric tonnes. Large numbers of dead round goby Neogobius melanostomus were also seen, as well as a few muskellunge Esox masquinongy. In the drum, there was a consistent histological pattern of variably severe panvasculitis, a necrotising myocarditis, meningoencephalitis and a segmental enteritis. Moderate numbers of bullet-shaped viral particles consistent with a rhabdovirus were identified by transmission electron microscopy (TEM) in affected heart tissue. Following primary isolation from pooled tissues on fathead minnow (FHM) cells, a morphologically similar virus, approximately 165 x 60 nm in size, was visualised. Identification of the isolate as viral haemorrhagic septicemia virus (VHSV) was confirmed by enzyme immunoassay and by polymerase chain reaction. An appropriately sized product (468 bp) of the G-glycoprotein gene (nucleotides [nt] 340 to 807) was generated with RNA extracted from FHM cell supernatant. Analysis of a 360 nt partial glycoprotein gene sequence (nt 360 to 720) indicated a 96.4 to 97.2% nucleotide identity with known strains of North American (NA) VHSV. Analysis using Neighbour-joining distance methods assigned the isolate to the same lineage as the NA and Japanese isolates (Genogroup IV). However, there was sufficient sequence divergence from known NA VHSV isolates to suggest that this isolate may represent a distinct subgroup. The effects of ongoing mortality in freshwater drum and in multiple species during spring 2006 suggest that this newly recognised virus in the Great Lakes will have continued impact in the near future.     

Burn-induced increase in atrogin-1 and MuRF-1 in skeletal muscle is glucocorticoid independent but downregulated by IGF-I

The present study determined whether thermal injury increases the expression of the ubiquitin (Ub) E3 ligases referred to as muscle ring finger (MuRF)-1 and muscle atrophy F-box (MAFbx; aka atrogin-1), which are muscle specific and responsible for the increased protein breakdown observed in other catabolic conditions. After 48 h of burn injury (40% total body surface area full-thickness scald burn) gastrocnemius weight was reduced, and this change was associated with an increased mRNA abundance for atrogin-1 and MuRF-1 (3.1- to 8-fold, respectively). Similarly, burn increased polyUb mRNA content in the gastrocnemius twofold. In contrast, there was no burn-induced atrophy of the soleus and no significant change in atrogin-1, MuRF-1, or polyUb mRNA. Burns also did not alter E3 ligase expression in heart. Four hours after administration of the anabolic agent insulin-like growth factor (IGF)-I to burned rats, the mRNA content of atrogin-1 and polyUb in gastrocnemius had returned to control values and the elevation in MuRF-1 was reduced 50%. In contrast, leucine did not alter E3 ligase expression. In a separate study, in vivo administration of the proteasome inhibitor Velcade prevented burn-induced loss of muscle mass determined at 48 h. Finally, administration of the glucocorticoid receptor antagonist RU-486 did not prevent burn-induced atrophy of the gastrocnemius or the associated elevation in atrogin-1, MuRF-1, or polyUb. In summary, the acute muscle wasting accompanying thermal injury is associated with a glucocorticoid-independent increase in the expression of several Ub E3 ligases that can be downregulated by IGF-I.     

Transglucosidic reactions of the Aspergillus niger family 3 beta-glucosidase: qualitative and quantitative analyses and evidence that the transglucosidic rate is independent of pH

The hydrolytic and transglucosidic reactions of the Aspergillus niger Family 3 beta-glucosidase were characterized. Michaelis-Menten plots of the rates of aglycone formation were normal (hyperbolic) at low [substrate]. However, at high [substrate] the rates decreased at pH below approximately 5.5 but increased at pH above approximately 5.5. Each decrease or increase took the form of a second hyperbola adjoining the first. Thin layer chromatography, gas-liquid chromatography, and NMR analyses indicated that the substrates became transglucosidic acceptors when present at high concentrations. When pNPGlc and cellobiose reacted as acceptors, the C6 hydroxyl of the non-reducing substrate component reacted to form beta-D-glucopyranosyl-(1-6)-beta-D-glucopyranosyl-p-nitrophenol and beta-D-glucopyranosyl-(1-6)-beta-D-glucopyranosyl-(1-4)-D-glucopyranose, respectively. The acceptor action accounted for the second adjoining hyperbolas. Rate equations were derived for the production of the aglycone and the transglucosidic intermediate, and these equations described the data very well. Hydrolytic Vmax {Vmax(h)}, hydrolytic Km {Km(h)}, transglucosidic Vmax {Vmax(t)}, and transglucosidic Km {Km(t)} values were obtained by non-linear regression analysis using these equations. Vmax(h) pH profiles were bell shaped with optima between pH 4 and 4.5 but the Vmax(t) values did not change substantially between pH 3 and 7. These differences in the pH profiles explain the decreasing and increasing adjoining hyperbolas since Vmax(t) is lower than Vmax(h) at pH less than approximately 5.5 but higher than Vmax(h) at pH greater than approximately 5.5. The reason for these pH effects is that the value of the hydrolytic rate constant (k3) decreases while the value of the transglucosidic rate constant (k4) does not change between pH 3 and 7. The study also showed that gentiobiose forms by an intermolecular reaction of the C6 hydroxyl of Glc rather than an intramolecular reaction and that an equatorial orientation of the C2 hydroxyl, the presence of a C6 primary hydroxyl and beta-linkages with oligosaccharide acceptors are important for acceptor reactivity.     

Sucrose Synthase: Expanding Protein Function

Sucrose synthase (SUS: EC 2.4.1.13), a key enzyme in plant sucrose catabolism, is uniquely able to mobilize sucrose into multiple pathways involved in metabolic, structural, and storage functions. Our research indicates that the biological function of SUS may extend beyond its catalytic activity. This inference is based on the following observations: (a) tissue-specific, isoform-dependent and metabolically-regulated association of SUS with mitochondria and (b) isoform-specific and anoxia-responsive interaction of SUS with the voltage-dependent anion channel (VDAC), the major outer mitochondrial membrane protein. More recent work shows that both VDAC and SUS are also localized to the nucleus in maize seedling tissues. Their intricate regulation under anoxia indicates that these two proteins may have a role in inter-compartmental signaling.Key Words: sucrose synthase, mitochondria, nucleus, localization, voltage-dependent anion channel (VDAC), non-catalytic rolesThe biochemical function of a protein is encoded within its primary sequence and can often be deciphered by simple in vitro assays. The cellular or organismal function of a protein is frequently the same as its biochemical activity. However, for many proteins, the biological function cannot be easily derived based on its biochemical function. This appears to be particularly true when the gene encoding the protein has a history of duplication and is represented by a family of paralogs. In maize and other species, sucrose synthase (SUS) isoforms are almost identical in their catalytic properties.^1,2 However, the characteristic phenotypes of mutants in specific isoforms suggest that the isoforms contribute to vastly different organismal functions.^2–4 Our interest is to identify the range of functions that maize SUS isoforms may have and elucidate the molecular basis of this functional diversity. Although expression divergence and consequent variation in their cellular abundance significantly contributes to this diversity,⁵ other factors such as intracellular distribution, post-translational modifications and interacting partners,^3,4,6,7 seem to be equally critical for the functional diversification of different SUS isoforms.Our study, spurred by a bioinformatics prediction, opened up a new facet of SUS biology, in that the protein may have organelle-based functions.⁸ Our analysis indicated that two of the three maize SUS isoforms (SH1 and SUS1) partly localize to mitochondria and nuclei, compartments not related to sucrose metabolism. In addition to this isoform-specificity, the compartmentation of SUS isoforms is influenced by developmental as well as environmental cues. Furthermore, its isoform-specific interaction with the voltage-dependent anion channel (VDAC) and an apparent conservation of SUS mitochondrial targeting across plant species suggest that SUS may have novel, noncatalytic biological functions. Our recent work shows that along with SUS, VDAC is also localized to the nucleus and these two proteins are inversely regulated in these two compartments under anoxic stress, indicating SUS-VDAC interaction may play a role in inter-compartmental signaling (Fig. 1).Open in a separate windowFigure 1Current working model of SUS-VDAC interactions in maize root tip cells. Prolonged anoxia leads to de-oligomerization of VDAC and the release of SUS from mitochondria, resulting in the migration of SUS to the nucleus. We hypothesize that the nuclear accumulation of SUS signals the induction of cell death pathway leading to the death of the root tip in anoxic maize seedlings. The insets show the primary root tip and a part of the axis from aerobic and anoxic seedlings. The root tip death is indicated by Evans Blue staining pattern of the anoxic root. ≠ = SUS. □ = VDAC.SUS mitochondrial localization also provided us an opportunity to reinterpret the phylogeny of sucrose metabolism. The proposed origin of sucrose metabolism is equivocal between the proteobacterial and cyanobacterial lineages.^9,10 Our discovery of SUS inside mitochondria, absence of plastid-bound SUS or plastid-targeting information in any of the plant SUS proteins and occurrence of mitochondrial targeting information in proteobacterial SUS orthologs strongly support a proteobacterial origin of plant sucrose synthases.⁸ Based on a genome-wide analysis of E. coli proteins, Lucattini et al.¹¹ proposed that mitochondrial targeting information may have been derived from the preexisting sequences of the endosymbiont proteins. We hypothesize that, in addition to the structural features needed for mitochondrial association, the functional basis of SUS-VDAC interaction may have been recruited by plants from the prokaryotic SUS genes. Based on striking similarities between bacterial and mitochondrial porins in their structure as well as regulation by purine nucleotides and their role in the host-cell death as modulated by cellular ATP levels, Frade and Michaelidis¹² speculated that the eukaryotic programmed cell death may have been a consequence of acquiring aerobic metabolism via the endosymbiotic process. Is organellar SUS a part of this acquisition?