Heme binding and polymerization by Plasmodium falciparum histidine rich protein II: influence of pH on activity and conformation.

The histidine rich protein II (HRPII) from Plasmodium falciparum has been implicated as a heme polymerase which detoxifies free heme by its polymerization to inactive hemozoin. Histidine-iron center coordination is the dominant mechanism of interaction between the amino acid and heme. The protein also contains aspartate allowing for ionic/coordination interactions between the carboxylate side chain and the heme metal center. The pH profile of heme binding and polymerization shows the possibility of these two types of binding sites being differentiated by pH. Circular dichroism studies of the protein show that pH and heme binding cause a change in conformation above pH 6 implying the involvement of His-His+ transitions. Heme binding at pHs above 6 perturbs HRPII conformation, causing an increase in helicity.     

Glutathione as an inhibitor of trypsin induced proteolysis

Glutathione has been shown to inhibit trypsin induced proteolytic activity. A concentration of 6 mM of glutathione was found to completely inhibit proteolysis of 3H-proline labelled underhydroxylated procollagen as a substrate, whereas a concentration of 2.1 mM of glutathione caused 50% inhibition of proteolysis. When azocoll was used as a substrate for trypsin 50% inhibition of proteolysis was achieved with 1.4 mM of glutathione, though a complete proteolytic inhibition was attained at 4 mM glutathione. The results suggest that glutathione may be playing an important role in protein metabolism in a variety of disease and stress states.     

Calcium diphosphatidate membrane traversal is inhibited by common phospholipids and cholesterol but not by plasmalogen

Phosphatidate-mediated Ca2+ membrane traversal is inhibited by phospholipids (PL) such a phosphatidylcholine (PC), phosphatidylinositol (PI), phosphatidylserine (PS), sphingomyelin and lysoPC, but not by PC-plasmalogen. Kinetics of Ca2+ traversal through a 'passive' bilayer consisting of OH-blocked cholesterol show competition between PC and phosphatidic acid (PA); it appears likely that a Ca(PA.PC) complex is formed which is not a transmembrane ionophore but will reduce the amount of phosphatidic acid available for the formation of the ionophore, Ca(PA)2. PS and PI may inhibit Ca2+-traversal in the same manner by forming Ca(PA.PL) complexes. We suggest that PC-plasmalogen, with one of the Ca2+-chelating ester CO groups missing, cannot engage in calcium cages, i.e., Ca(PA.PL) complexes, and thus does not interfere with Ca(PA)2 formation. Double-reciprocal plotting of Ca2+ traversal rates in cholesterol-containing liposomes vs. calcium concentration suggests that cholesterol inhibits Ca2+ traversal by competing with Ca2+ for PA. The inhibition does not seem to be caused by a restructuring or dehydration of the membrane 'hydrogen belts' affected by cholesterol; most probably, it is due to hydrogen bonding of the cholesterol-OH group to a CO group of PA; this reduces the amount of PA available for the calcium ferry. The inhibition by sphingomyelin and lysoPC may also be explained by their OH group interacting with PA via hydrogen bonding. The pH dependence of Ca2+ traversal suggests that H[Ca(PA)2]- can serve as Ca2+ cross-membrane ferry but that at physiological pH, [Ca(PA)2]2- is the predominant ionophore. In conclusion, the results indicate that Ca2+ traversal is strongly dependent on the structure of the hydrogen belts, i.e., the membrane strata occupied by hydrogen bond acceptors (CO of phospholipids) and donors (OH of cholesterol, sphingosine), and that lipid hydrogen belt structures may regulate storage and passage of Ca2+.     

Preparation of passive bilayer liposomes

In studies of in-membrane molecular interactions, need may arise for a matrix that cannot itself interact, except hydrophobically, with the reactants. Such a bilayer matrix should, ideally, consist of only a hydrophobic zone without ionic outer layers and without hydrogen belts (the membrane strata containing CO and OH groups). However, because of the necessity of anchoring the bilayer to its aqueous surroundings, there must be polar substituents. Hydrophilic ether groups in the form of polyoxyethylenes can provide nearly sufficient anchoring and yet not confer unwanted reactivity to the membrane since they are only very weak H-bond acceptors. The stability of the bilayer is ensured by the presence of a few percent of an amphiphile (which may be the substrate to be studied, e.g. a phospholipid) or by a free polyethylene hydroxy group far remote from the original hydrogen belt region. Our most impermeable liposomes consisted of O-methylcholesterol/O-methoxyethoxyethoxyethylcholesterol; the most readily prepared liposomes were made from O-methylcholesterol and hydroxy(ethoxy)4dodecane (Brij 30) or Triton.     

Phosphatidylcholine and cholesterol inhibit phosphatidate-mediated calcium traversal of liposomal bilayers

Rates of phosphatidic acid- (PA-) mediated Ca2+-traversal are maximal in 'passive bilayers' void of lipid CO and OH groups: dietherphosphatidylcholine (diether-PC) or OH-blocked cholesterol liposomes. Phosphatidylcholine (PC) as bilayer matrix causes 99% inhibition, while 45 mol% cholesterol in passive bilayers inhibits by about 70%. Possibly, the absence of CO and OH groups causes a dehydration of the 'hydrogen belts', i.e., the membrane strata occupied by hydrogen bond acceptors (CO of phospholipids) and donors (OH of cholesterol, sphingosine) and thereby facilitates the formation of dehydrated Ca(PA)2, the ionophoric vehicle; or (our preferred explanation) PC engages in a (non-ionophoric) Ca(PA X PC) complex and thus reduces the concentration of the ionophore, while cholesterol competes with Ca2+ for the CO groups of phosphatidic acid by hydrogen-bonding. The Ca2+-traversal rates realized in bilayers with modified hydrogen belts lend support to the speculation that a Ca(PA)2 ferry may be of physiological importance, e.g., in membranes (such as myelin) containing much ether phospholipid (plasmalogen); and that Ca2+-membrane association and traversal may be controlled by the composition of the hydrogen belts.     

Cytogenetical effects of ageing in seeds

Freshly harvested seeds of soybean and barley were artificially aged. The progeny showed a marked decrease in mitotic index and chromosomal aberrations of various types increased at both mitosis and meiosis, resulting in a significant loss of pollen viability as the ageing advanced. Studies on the types and frequencies of chlorophyll deficients and phenodeviants also showed an overall increase, suggesting that ageing mimics irradiation effects and produces alterations in the gene complexes resulting in the segregation of different kinds of phenotypic mutations.     

Production of disease-free encapsulated buds of Zingiber officinale Rosc.

Shoot buds of ginger were successfully encapsulated in 4% sodium alginate gel. Encapsulated buds were germinated in vitro to form roots and shoots. In vitro germination (emergence of sprouts) of encapsulated buds ranged from 16.7% to 81.8% on different media after 5 weeks of incubation. Normal plantlets with an average shoot length of 2.3 cm and 1.7 cm root length were successfully transplanted into unsterilized soil without any hardening process. These plantlets showed no symptoms of ginger yellows disease and the causal fungal pathogen failed to grow out on culture media (used as a diagnostic test).     

An improved medium for in vitro grain development from detached wheat spikelets

Wheat spikelets detached from the spike at anthesis were cultured on solidified media and successfully produced mature grains. These grains resembled normal grains and contained well-developed, embryos. Lower concentrations of glutamine favored dry weight increase in developing grains. Such grains were indistinguishable from grains from greenhouse-grown plants in germination on moist blotting sheets. The technique of individual spikelet culture can be used to study physiology and development of wheat grains and kernels and to study host-pathogen interactions in wheat floret diseases such as Karnal bunt.