Condensed tannins deter feeding by browsing ruminants in a South African savanna

Summary The palatability of 14 species of woody plant was assessed for three species of browsing ruminant, namely kudus, impalas and goats. Results show that palatability was most clearly related to leaf contents of condensed tannins. The effect was a threshold one, with all plants containing more than 5% condensed tannins being rejected as food during the wet season period. In contrast palatability was not influenced by concentrations of protein-precipitating polyphenols, and only weakly related to contents of nitrogen, phosphorus, cations, fibre components and other secondary metabolites. Insect herbivory shows a different pattern. These findings support the hypotheses that (i) condensed tannins function to protect plant cell walls against microbial attack; (ii) hydrolyzable tannins function to inactivate the digestive enzymes of insect herbivores. Large mammalian herbivores are influenced by condensed tannins due to their dependance upon microbial fermentation of plant cell walls for part of their energy needs.     

A developmentally regulated hydroxyproline-rich glycoprotein from the cell walls of soybean seed coats

In soybean seeds the level of hydroxyproline is regulated in a developmental and tissue-specific manner. The seed coat contains approximately 77% of the total hydroxyproline in the seed at all stages of development. We determined the ratio of hydroxyproline to dry weight in a number of tissues within the seed; however, only the seed coat shows an increase in this ratio during development. Within the many cell layers of the seed coat, hydroxyproline is most abundant in the external layer. The hydroxyproline is present as an hydroxyproline-rich cell wall glycoprotein. The protein is rich in hydroxyproline (36%), lysine (11%), proline (10%), histidine (9%), tyrosine (9%), and serine (8%). The carbohydrate portion is 90 mole% arabinose and 10 mole% galactose. The arabinose residues are attached to hydroxyproline mostly in the form of trisaccharides. The apparent molecular weight of this glycoprotein is 100,000 daltons.     

Partition kinetics of ribulose-1,5-bisphosphate carboxylase from Rhodospirillum rubrum

When the enzymatically generated intermediate 2-carboxy-3-keto-D-arabinitol-1,5-bisphosphate (II) was used as a substrate with fresh enzyme, 70% reacted to produce 3-phosphoglycerate (3PGA). When a reaction mixture of enzyme plus [1-32P]ribulose 1,5-bisphosphate (RuBP) was quenched in the steady state with the tightly bound inhibitor 2-carboxyarabinitol-1,5-bisphosphate, 30% of the enzyme-bound species was released as 3PGA and 70% as RuBP. The major source for this partition was the ternary substrates Michaelis complex. The level of carboxylated intermediate in the steady state was determined to be 8% of active sites under the conditions of substrate saturation. No burst was seen in the appearance of product when 6.5 eq of [1-32P]RuBP was mixed with enzyme plus saturating CO2 and the reaction followed in the steady state. From these data plus the steady-state Vmax and Km of RuBP it is possible to derive the five bulk rate constants represented in the scheme ECO2 + RuBP in equilibrium ERuBPCO2 in equilibrium E X II----E + 2(3PGA).     

Chloride transport across the integumentary epithelium ofManduca sexta (Lepidoptera: Sphingidae)

Summary Moulting fluid ofManduca sexta contains high concentrations of potassium and bicarbonate (100 mM) and low concentrations of chloride (5 mM). This fluid begins to disappear from the exuvial space approximately 9–10 h before the actual shedding of the integument. During this time, the integument can be isolated in an Ussing cell and electrical properties measured in vitro. In a normal 32 mM KHCO₃ saline, potential difference (PD) is around 10 mV, exuvial side positive, and short-circuit current (SCC) is 15–20 A cm^–2. Substitution of chloride slightly reduces both PD and SCC, although resistance does not change significantly. Measurement of chloride transport in the absence of K⁺ indicates that 100% of the SCC can be accounted for by the net chloride flux (2 A cm^–2). TheK _m andJ _max for transepithelial chloride transport are 14 mM and 0.1 Eq cm^–2 h^–1. Bilateral potassium addition stimulates chloride transport, doubling net chloride flux as potassium concentration increases from 2 to 5 mM. Chloride net flux is not inhibited by the presence of furosemide (1 mM), nor in HCO ₃ ^– -free saline by thiocyanate (1 or 10 mM) or acetazolamide (0.1 mM), but is inhibited by 100% N₂. The pattern of chloride transport inM. sexta is similar to that previously reported for the rectum of locusts. As chloride is normally at low concentrations in the moulting fluid, it is suggested that this transport system acts to maintain low intracellular concentrations which may be necessary for enzymatic functions in the epidermal cells and has little importance in fluid transport.Abbreviations PD potential difference - PPI pharate pupal integument - SCC short circuit current In the time since this research was performed, A.M. Jungreis passed away. He will be missed by his friends and colleagues     

Structural requirements of a membrane-spanning domain for protein anchoring and cell surface transport

The membrane-spanning domain of the vesicular stomatitis virus glycoprotein (G) contains 20 uncharged and mostly hydrophobic amino acids. We created DNAs specifying G proteins with shortened transmembrane domains, by oligonucleotide-directed mutagenesis. Expression of these DNAs showed that G proteins containing 18, 16, or 14 amino acids of the original transmembrane domain assumed a transmembrane configuration and were transported to the cell surface. G proteins containing only 12 or 8 amino acids of this domain also spanned intracellular membranes, but their transport was blocked within a Golgi-like region in the cell. A G protein completely lacking the membrane-spanning domain accumulated in the endoplasmic reticulum and was secreted slowly. These experiments indicate that the size of the transmembrane domain is critical not only for membrane anchoring, but also for normal cell surface transport.     

Testing of microbial demulsifiers with heavy crude emulsions

Summary It has already been demonstrated that model water-in-kerosene systems and toluene diluted heavy crude oil emulsions can be broken by microbial agents. In this studyN. amarae andR. rhodochrous are used on undiluted, water-in-heavy crude oil emulsions. The high viscosity of the undiluted emulsions severely limits the demulsifying ability of the bacteria towards these field emulsions.     

Magnesium ion exerts a central role in the regulation of inhibitory adenosine receptors.

Guanine nucleotides and Mg2+ differentially regulate agonist binding to adenosine (Ri) receptors in fat-cell plasma membranes. GTP alone decreases binding of the agonist ligand [3H]N6-cyclohexyladenosine (CHA) by increasing the dissociation constant (Kd). Mg2+ alone also decreases [3H]CHA binding, which is associated with a decrease in the number of receptors and in the dissociation constant. In the presence of Mg2+, the effect of GTP is to increase [3H]CHA binding by increasing the total number of receptors. It thus appears that Mg2+ acts specifically at a bivalent-cation site which, with GTP, regulates agonist binding. This putative Mg site is highly sensitive to alkylating agents. Mild treatment with N-ethylmaleimide (NEM) abolishes the characteristic GTP effect on agonist binding in the presence of Mg2+. In addition, the effect of Mg2+ alone is also eliminated. The effect of GTP alone is largely unaltered. Studies of the adenylate cyclase activity indicate that this NEM treatment also abolishes the inhibition of basal activity by adenosine analogues, whereas guanylyl imidodiphosphate inhibition of forskolin-stimulated activity is only slightly impaired at this NEM concentration. These observations indicate that a Mg2+ 'site' or 'component' is required for the integration of receptor (Ri) occupancy with regulation of catalytic activity (C). The regulatory role of Mg2+ is more demonstrable in receptor-GTP-regulatory-protein (Ri-Ni) interactions than in GTP-regulatory-protein-catalytic-unit (Ni-C) interactions.