The human genes for the α and γ subunits of the mast cell receptor for immunoglobulin E are located on human chromosome band 1823

The receptor with high affinity for immunoglobulin E (FcERI) is a key molecule in triggering the allergic reaction. It is tetrameric complex of one subunit, one subunit, and two disulfide-linked subunits. This receptor is present exclusively on mast cells and basophils. Molecules identical to the subunit of FcRI also form cell surface complex with other Fc receptors such as mouse FcRIIa in macrophages and most probably with human FcRIII (CD16) in natural killer (NK) cells. Here we show by in situ hybridization that the human genes for the (FCER1A) and subunits (FCER1 G) of FcERI and the gene for FcRIII (FCGR3, CD16) are located on human chromosome band 1823.     

Induction of Haem Oxygenase as a Defence Against Oxidative Stress

Cells respond to metabolic perturbations by producing specific stress proteins. Exposure of mammalian cells to various forms of oxidative stress induces haem oxygenase, the rate-limiting enzyme in haem degradation. This response is proposed to represent an antioxidant defence operating at two different stages simultaneously. It (i) decreases the levels of the potential pro-oxidants haem and haem proteins such as cytochrome P-450 and protoporphyrinogen oxidase, and (ii) increases the tissue concentrations of antio-xidatively active bile pigments.     

A T7 promoter-specific, inducible protein expression system forBacillus subtilis

The adaptation and application of theEscherichia coli T7 RNA polymerase system for regulated and promoter-specific gene expression inBacillus subtilis is reported. The expression cassette used inBacillus subtilis was tightly regulated and T7 RNA polymerase (T7 RNAP) appeared 30 min after induction. The efficiency of T7 promoter-specific gene expression inB. subtilis was studied using one secretory and two cytosolic proteins of heterologous origin. The accumulation ofE. coli -galactosidase, as well as a 1,4--glucosidase fromThermoanaerobacter brockii inB. subtilis after T7 RNAP induction was strongly enhanced by rifampicin inhibition of host RNAP activity. The-amylase ofThermoactinomyces vulgaris, a secretory protein, was found to accumulate in the culture supernatant up to levels of about 70 mg/l 10–20 h after T7 RNAP induction, but was also deposited in cellular fractions. The addition of rifampicin inhibited-amylase secretion, but unexpectedly, after a short period, also prevented its further (intra)cellular accumulation     

Constitutively hyposialylated human T-lymphocyte clones in the Tn-syndrome: binding characteristics of plant and animal lectins

Previously, 1,3-galactosyltransferase-deficient (Tn+) and normal (TF+) T-lymphocyte clones have been established from a patient suffering from Tn-syndrome [Thurnheret al. (1992)Eur J Immunol 22: 1835–42], Tn+ T lymphocytes express only Tn antigen (GalNAc1-O-R) while other O-glycan structures such as sialosyl-Tn (Neu5Ac2,6GalNAc1-O-R) or TF (Gal1-3GalNAc1-O-R) antigens are absent from these cells as shown by flow cytometry using specific mABs for TF and sialosyl-Tn antigen, respectively. Normal T lymphocytes express the TF antigen and derivatives thereof. The surface glycans of Tn+ and TF+ cells were then analysed by flow cytometry using the following sialic acid-binding lectins:Amaranthus caudatus (ACA),Maackia amurensis (MAA),Limax flavus (LFA),Sambucus nigra (SNA) andTriticum vulgare (WGA). Equal and weak binding of MAA and SNA to both TF+ and Tn+ cells was found. WGA, LFA and ACA bound more strongly to TF+ cells than to Tn+ cells. Binding of ACA to TF+ cells was enhanced after sialidase treatment. To investigate the possible biological consequences of hyposialylation, binding of three sialic acid-dependent adhesion molecules to Tn+ and TF+ cells was estimated using radiolabelled Fc-chimeras of sialoadhesin (Sn), myelin-associated glycoprotein (MAG) and CD22. Equal and strong binding of human CD22 to both TF+ and Tn+ cells was found. Whereas binding of Sn and MAG to TF+ cells was strong (100%), binding to Tn+ cells amounted only to 33% (Sn) and 19% (MAG). These results indicate that thein vivo interactions of T lymphocytes in the Tn syndrome with CD22 are not likely to be affected, whereas adhesion mediated by Sn or MAG could be strongly reduced.     

Partial purification of a plasma membrane flavoprotein and NAD(P)H-oxidoreductase activity

Plasma membrane flavins and pterins are considered to mediate important physiological functions such as blue light photoperception and redox activity. Therefore, the presence of flavins and pterins in the plasma membrane of higher plants was studied together with NAD(P)H-dependent redox activities. Plasma membranes were isolated from the apical hooks of etiolated bean seedlings (Phaseolus vulgaris L. cv. Limburgse Vroege) by aqueous two-phase partitioning. Fluorescence spectroscopy revealed the presence of two chromophores. The first showed excitation maxima at 370 and 460 nm and an emission peak at 520 nm and was identified as a flavin. The second chromophore was probably a pterin molecule with excitation peaks at 290 and 350 nm and emission at 440 nm. Both pigments are considered intrinsic to the plasma membrane since they could not be removed by treatment with hypotonic media containing high salt and low detergent concentrations. The flavin concentration was estimated at about 500 pmol mg^?1 protein. However difficulties were encountered in quantifying the pterin concentrations. Protease treatments indicated that the flavins were non-covalently bound to the proteins. Separation of the plasma membrane proteins after solubilisation by octylglucoside, on an ion exchange system (HPLC, Mono Q), resulted in a distinct protein fraction showing flavin and pterin fluorescence and NADH oxidoreductase activity. The flavin of this fraction was identified as flavin mononucleotide (FMN) by HPLC analysis. Other minor peaks of NADH:acceptor reductase activity were resolved on the column. The presence of distinct NAD(P)H oxidases at the plasma membrane was supported by nucleotide specificity and latency studies using intact vesicles. Our work demonstrates the presence of plasma membrane flavins as intrinsic chromophores, that may function in NAD(P)H-oxidoreductase activity and suggests the presence of plasma membrane bound pterins.     

A survey of alkaloids in the genera Harpalyce and Brongniartia (Fabaceae—Brongniartieae)

The presence of alkaloids in six species of Brongniartia and three species of Harpalyce is reported. This survey revealed remarkable qualitative differences in the alkaloid profiles of these two genera. B. discolor, B. lupinoides, B. sousae and B. intermedia showed a typical -pyridone pattern, with cytisine, anagyrine and baptifoline as major alkaloids. In leaves of the first three species ormosanine-type alkaloids occurred additionally. B. flava and B. vazquezii are devoid of -pyridones, but accumulate lupanine, hydroxylated lupanines and ester alkaloids. All three species of Harpalyce were similar in accumulating -pyridones, but H. formosa differed from H. brasiliana and H. pringlei in the presence of epilupinine. In general the alkaloid profiles of Brongniartia and Harpalyce show similarities to those of the Australian genera Hovea, Lamprolobium, Plagiocarpus and Templetonia and support therefore the actual concept of the enlarged tribe Brongniartieae.     

Synthetic substrate analogues for UDP-GlcNAc: Manα1-6R β(1-2)-N-acetylglucosaminyltransferase II. Substrate specificity and inhibitors for the enzyme

UDP-GlcNAc: Man1-6R (1-2)-N-acetylglucosaminyltransferase II (GlcNAc-T II; EC 2.4.1.143) is a key enzyme in the synthesis of complexN-glycans. We have tested a series of synthetic analogues of the substrate Man1-6(GlcNAc1-2Man1-3)Man-O-octyl as substrates and inhibitors for rat liver GlcNAc-T II. The enzyme attachesN-acetylglucosamine in 1-2 linkage to the 2-OH of the Man1-6 residue. The 2-deoxy analogue is a competitive inhibitor (K _i=0.13mm). The 2-O-methyl compound does not bind to the enzyme presumably due to steric hindrance. The 3-, 4- and 6-OH groups are not essential for binding or catalysis since the 3-, 4- and 6-deoxy and -O-methyl derivatives are all good substrates. Increasing the size of the substituent at the 3-position to pentyl and substituted pentyl groups causes competitive inhibition (K _i=1.0–2.5mm). We have taken advantage of this effect to synthesize two potentially irreversible GlcNAc-T II inhibitors containing a photolabile 3-O-(4,4-azo)pentyl group and a 3-O-(5-iodoacetamido)pentyl group respectively. The data indicate that none of the hydroxyls of the Man1-6 residue are essential for binding although the 2- and 3-OH face the catalytic site of the enzyme. The 4-OH group of the Man-O-octyl residue is not essential for binding or catalysis since the 4-deoxy derivative is a good substrate; the 4-O-methyl derivative does not bind. This contrasts with GlcNAc-T I which cannot bind to the 4-deoxy-Man- substrate analogue. The data are compatible with our previous observations that a bisectingN-acetylglucosamine at the 4-OH position prevents both GlcNAc-T I and GlcNAc-T II catalysis. However, in the case of GlcNAc-T II, the bisectingN-acetylglucosamine prevents binding due to steric hindrance rather than to removal of an essential OH group. The 3-OH of the Man1-3 is an essential group for GlcNAc-T II since the 3-deoxy derivative does not bind to the enzyme. The trisaccharide GlcNAc1-2Man1-3Man-O-octyl is a good inhibitor (K _i=0.9mm). The above data together with previous studies indicate that binding of the GlcNAc1-2Man1-3Man- arm of the branched substrate to the enzyme is essential for catalysis. Abbreviations: GlcNAc-T I, UDP-GlcNAc:Man1-3R (1-2)-N-acetylglucosaminyltransferase I (EC 2.4.1.101); GlcNAc-T II, UDP-GlcNAc:Man1-6R (1-2)-N-acetylglucosaminyltransferase II (EC 2.4.1.143); MES, 2-(N-morpholino)ethane sulfonic acid monohydrate.     

The Larval Eye of Nannochoristid Scorpionflies (Insecta,Mecoptera)

Abstract The stemmata of last–instar Nannochoristalarvae are compound eyes composed of 10 or more ommatidia. Each ommatidium has four Semper cells, four distal and four proximal retinula cells which form a cruciform and layered rhabdom. The ommatidia are separated by epidermal cells (possibly rudimentary pigment cells). Corneal lenses are lacking. At the posterior edge, aberrant stemma units may be present which lack a dioptric apparatus and have a star–shaped rhabdom composed of at least six retinula cells. The stemmata of Nannochoristaappear to be derived from stemmata of the Panorpa-type (Mecoptera-Panorpidae). Differences between the stemmata of Nannochoristaand Panorpacan be explained as adaptations to aquatic life (flat cornea) or as regression. A compound larval eye is ascribed to the ground plan of the Mecoptera sensu latoand is considered a genuine plesiomorphy. The identical basic number (seven) of stemmata in the Neuropteroid/Coleoptera assemblage, Amphiesmenoptera and some Mecoptera (Bittacidae, Boreidae) is attributed to parallel evolution.     

Ern?hrungsphysiologie des Blaunackenmausvogels (Urocolius macrourus pulcher)

Zusammenfassung Beim Blaunackenmausvogel (Urocolius macrourus pulcher) wurde die Ausnutzung der verschiedenen Nährstoffe (Fette, Eiweiße, Kohlenhydrate) und die Assimilationseffizienz des Gesamtfutters untersucht. Mausvögel sind Vegetarier und hauptsächlich frugivor. Im Versuch erhielten die Vögel vier Diäten: I. Mischfutter (Bananen, Salat, gekochtes Ei, gekochter Reis, Apfel); II. Bananen; III. Fruchtfutter (Pfirsiche und Birnen); IV. Eiweißfutter (Quark und gekochtes Weißei). Die minimalen Darmpassagezeiten betrugen für alle vier Diäten zusammengefaßt zwischen 6 und 18 min. Damit kommen die Mausvögel an die Werte für Nektarfresser heran (unter 15 min). Der Darmtrakt ist mit 19,0 ±2,4 cm (n = 16) für einen Vogel dieser Körpermasse ( 56,4 ±2,7 g; 49,2 ±2,9 g) extrem kurz und zeigt den für Fruchtfresser typischen einfachen Bau. Blinddärme fehlen. Die mittlere Gesamteffizienz für die vier Diäten liegt bei 71,0 %. Die Werte variieren in einem relativ engen Bereich zwischen 65,9 % (Banane) und 74,0 % (Mischfutter). Damit sind Blaunackenmausvögel innerhalb der Vögel als relativ schlechte Nahrungsverwerter zu bezeichnen. Für Fruchtfresser allgemein werden allerdings noch niedrigere Werte zwischen 30 % und 70 % angegeben. Die Assimilationsrate der einzelnen Nährstoffe hängt in starkem Maße vom Angebot im Futter ab. Die Zusammensetzung der assimilierten Nahrung zeigt, daß Kohlenhydrate mit 89,0–91,1 % den weitaus größten Anteil am Energiestoffwechsel haben. Vermutlich werden nur gelöste oder leicht verdauliche Einfachzucker bzw. Stärken verwertet. Zellulose wird praktisch ungenutzt ausgeschieden. Fette und Proteine spielen unter Normalbedingungen nur eine untergeordnete Rolle. Der Energieumsatz ist nahrungsabhängig und beträgt 62,5 J/g·h bei der Bananendiät, 69,2 J/g·h bei der Fruchtdiät, 87,3 J/g·h bei der Eiweißdiät und 99,6 J/g·h beim Mischfutter.

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Nutrient physiology of the Blue-naped Mousebird (Urocolius macrourus pulcher)

Blue-naped Mousebirds were fed with four different diets: I. mixed food (bananas, salad, boiled eggs, boiled rice, apples); II. bananas only; III. soft fruits (pears and peaches); and IV. food enriched with protein (curd cheese and egg-white). The minimal times for food passage through the digestive tract were 6–18 min altogether. This is similar to the data known from nectarivorous birds (<15 min). The intestines are extremely short (19,0 ±2,4 cm; n = 16) and simple-structured, without specialization and without any caeca. The overall efficiency for the diets with 71,0 %, ranging between 65,9 % (bananas) and 74,0 % (mixed food), is relatively low. However, for frugivorous birds in general, far lower efficiencies are recorded (30–70 %). The assimilation efficiencies of nutrients depend on their amount in food and the physiological and seasonal requirements. The composition of the assimilated food shows that carbohydrates, having the largest part with 89,0–91,1 %, are most important for energy supply. Presumably, the birds utilize only sugars being easy to digest, because cellulose is removed. Fat and protein are playing a subordinate role in metabolism. The metabolic turnover differs with the diet and ranges between 62,5 J/g·h (bananas), 69,2 J/g·h (fruits), 87,3 J/g·h (protein food) and 99,6 J/g·h (mixed food).