Two classes of collagen-tailed,asymmetric molecular forms of acetylcholinesterase in skeletal muscle: differential effects of denervation

Skeletal muscles of different vertebrate species contain, as it is the case in other cholinergic tissues, two classes of collagen-tailed, asymmetric forms (A-forms) of acetylcholinesterase (AChE). Class I A-forms are readily brought into solution in the presence of high salt, while class II A-forms do additionally require a chelating agent, such as EDTA, for solubilization. All A-forms aggregate at low ionic strength but only class II A-forms are reaggregated by excess Ca⁺⁺, even in the presence of 1M NaCl. This Ca⁺⁺-mediated aggregability of class II A-forms is slowly lost upon exposure to detergents such as Triton X-100.Although these two classes of AChE tailed forms seem to be present in endplate and non-endplate areas, and in both the extra- and intracellular compartments, class II A-forms are predominantly extracellular and endplate-specific, at least in the rat diaphragm. On the other hand, well-characterized fast- and slow-twitch muscles show no preference for either class of asymmetric AChE species. Upon denervation, class I A-forms are degraded faster and disappear earlier than their class II counterparts, which are still easily detectable 17 days after nerve section.Class I and class II AChE molecular species exist in similar relative proportions in many vertebrate muscles. Thus, collagen-tailed forms may be altogether more abundant, in skeletal muscle, than it was hitherto realized.It is expected that this further example of AChE polymorphism will contribute to a better understanding of cholinergic transmission in skeletal muscle and, more specially, of nerve-muscle interactions.     

β-N-Oxalyl-L-α, β-diaminopropionic Acid in Somaclones Derived from Internode Explants of Lathyrus sativus

Protocols have been developed for in vitro regeneration from internode explants from Lathyrus sativus. Callus raised on B₅ medium supplemented with 10.7 μM NAA + 2.2 μM BA permitted shoot regeneration upon transfer to modified MS medium containing 10.7 μM NAA + 2.2 μM BA. Rooting was obtained only on 1/2 MS media containing 0.5 μM IBA. The in vitro regenerated plants, after primary and secondary hardening, were taken to the field. Analysis of ODAP in leaves and seeds was carried out. The low toxin containing progeny of the somaclones were further grown in the field. The toxin contents varied from 0.015% to 0.460% in leaf and 0.030% to 0.539% in seed in R, generation, as compared to 0.258% in leaf and 0.406% in seed for the parent P-24. Statistical analysis showed a positive significant correlation between leaf and seed ODAP contents. Mean seed toxin in R₁ generation of some of the somaclones varied from 0.039–0.057% and single plant seed yield varied from 25.8 to 45.0 g. Some plants showed seed toxin content of less than 0.01% from 1–22 progeny. Thus, following in vitro culture of internode explant, toxin content in seeds in R₂ generation has been found to be substantially reduced with single plant seed yield either equal to or higher than that of parent cv. P 24.     

The Ribosome Can Prevent Aggregation of Partially Folded Protein Intermediates: Studies Using the Escherichia coli Ribosome

Background

Molecular chaperones that support de novo folding of proteins under non stress condition are classified as chaperone ‘foldases’ that are distinct from chaperone’ holdases’ that provide high affinity binding platform for unfolded proteins and prevent their aggregation specifically under stress conditions. Ribosome, the cellular protein synthesis machine can act as a foldase chaperone that can bind unfolded proteins and release them in folding competent state. The peptidyl transferase center (PTC) located in the domain V of the 23S rRNA of Escherichia coli ribosome (bDV RNA) is the chaperoning center of the ribosome. It has been proposed that via specific interactions between the RNA and refolding proteins, the chaperone provides information for the correct folding of unfolded polypeptide chains.

Results

We demonstrate using Escherichia coli ribosome and variants of its domain V RNA that the ribosome can bind to partially folded intermediates of bovine carbonic anhydrase II (BCAII) and lysozyme and suppress aggregation during their refolding. Using mutants of domain V RNA we demonstrate that the time for which the chaperone retains the bound protein is an important factor in determining its ability to suppress aggregation and/or support reactivation of protein.

Conclusion

The ribosome can behave like a ‘holdase’ chaperone and has the ability to bind and hold back partially folded intermediate states of proteins from participating in the aggregation process. Since the ribosome is an essential organelle that is present in large numbers in all living cells, this ability of the ribosome provides an energetically inexpensive way to suppress cellular aggregation. Further, this ability of the ribosome might also be crucial in the context that the ribosome is one of the first chaperones to be encountered by a large nascent polypeptide chains that have a tendency to form partially folded intermediates immediately following their synthesis.     

HIV-1 promotes intake of Leishmania parasites by enhancing phosphatidylserine-mediated, CD91/LRP-1-dependent phagocytosis in human macrophages

Over the past decade, the number of reported human immunodeficiency virus type-1 (HIV-1)/Leishmania co-infections has risen dramatically, particularly in regions where both diseases are endemic. Although it is known that HIV-1 infection leads to an increase in susceptibility to Leishmania infection and leishmaniasis relapse, little remains known on how HIV-1 contributes to Leishmania parasitaemia. Both pathogens infect human macrophages, and the intracellular growth of Leishmania is increased by HIV-1 in co-infected cultures. We now report that uninfected bystander cells, not macrophages productively infected with HIV-1, account for enhanced phagocytosis and higher multiplication of Leishmania parasites. This effect can be driven by HIV-1 Tat protein and transforming growth factor-beta (TGF-β). Furthermore, we show for the first time that HIV-1 infection increases surface expression of phosphatidylserine receptor CD91/LRP-1 on human macrophages, thereby leading to a Leishmania uptake by uninfected bystander cells in HIV-1-infected macrophage populations. The more important internalization of parasites is due to interactions between the scavenger receptor CD91/LRP-1 and phosphatidylserine residues exposed at the surface of Leishmania. We determined also that enhanced CD91/LRP-1 surface expression occurs rapidly following HIV-1 infection, and is triggered by the activation of extracellular TGF-β. Thus, these results establish an intricate link between HIV-1 infection, Tat, surface CD91/LRP-1, TGF-β, and enhanced Leishmania phosphatidylserine-mediated phagocytosis.     

A pilot-scale study of struvite precipitation in a stirred tank reactor: conditions influencing the process

Currently, the two most developed techniques for recovering phosphorus from wastewater consist of the formation of calcium phosphates and struvite (MgNH(4)PO(4).6H(2)O). In this work the influence of the operational conditions on the struvite precipitation process (pH in the reactor, hydraulic retention time, and magnesium:phosphorus, nitrogen:phosphorus, and calcium:magnesium molar ratios) have been studied. Twenty-three experiments with artificial wastewater were performed in a stirred reactor. In order to obtain the pH value maintenance during the crystallization process, a fuzzy logic control has been developed. High phosphorus removal efficiencies were reliably achieved precipitating the struvite as easily dried crystals or as pellets made up of agglomerated crystals.     

Tuning of pulmonary arterial circulation evidenced by MR phase mapping in healthy volunteers.

Magnetic resonance (MR) phase mapping was used to noninvasively assess both blood flow and cross-sectional area (CSA) in the main pulmonary artery (MPA) of 12 healthy volunteers. Flow and CSA patterns exhibited two positive peaks: high systolic and small diastolic. This finding can be explained using a simple "distributed" theoretical model that takes into account the role of a reflected pressure wave from pulmonary vascular impedance in generating a diastolic flow. The mean reflection coefficient of pressure wave, MPA input impedance, and pulmonary vascular impedance were assessed. We verified, in this series, that pressure wave velocity appears to be age-dependent. MR phase mapping has been used to observe the tuning (resonance) of the right cardiovascular system at rest under physiological conditions. MR phase mapping could be used to assess pathological modifications of the tuning that occurs in cases of pulmonary arterial hypertension.     

Properties of human vasopressin precursor constructs: inefficient monomer folding in the absence of copeptin as a potential contributor to diabetes insipidus

These studies were aimed at an initial characterization of the human vasopressin precursor and the evaluation of factors leading to misfolding by the pathological 87STOP mutation. This mutation deletes the precursor's glycosylated copeptin segment, which has been considered unnecessary for folding, and the last seven neurophysin residues. We investigated the role in folding of the last seven neurophysin residues by comparing the properties of the 87STOP precursor and its derivative neurophysin with those of the corresponding wild-type proteins from which copeptin had been deleted, leading to the following conclusions. First, despite modulating effects on several protein properties, the last seven neurophysin residues do not make a significant net thermodynamic contribution to precursor folding; stabilities of the mutant and wild-type precursors to both guanidine denaturation and redox buffer unfolding are similar, as are in vitro folding rates. Second, the monomeric forms of both precursors are unstable and predicted to fold inefficiently at physiological pH and temperature, as evidenced by precursor behavior in redox buffers and by thermodynamic calculations. Third, both precursors are significantly less stable than the bovine oxytocin precursor. These results, together with earlier studies elsewhere of vasopressin precursor behavior within rat neurons, are shown to represent a self-consistent argument for a role for glycosylated copeptin in vasopressin precursor folding in vivo, copeptin most probably assisting refolding by facilitating interaction of misfolded monomers with the calnexin/calreticulin system. This hypothesis provides an explanation for the absence of copeptin in the more stable oxytocin precursor and suggests that the loss of copeptin contributes to 87STOP pathogenicity. Reported cell culture studies of rat precursor folding are also discussed in this context. Most generally, the results emphasize the significance of monomer stability in the folding pathways of oligomeric proteins.     

Guanine nucleotides, including GMP, antagonize kainate responses in Xenopus oocytes injected with chick cerebellar membranes

Injection of chick cerebellar membranes, rich in kainate binding sites, into Xenopus oocytes resulted in the structural integration of chick membrane patches into the oocyte plasma membrane that could be easily identified by specific immunofluorescent staining. Application of kainate to the oocyte perfusion medium, under voltage-clamp conditions, induced dose-dependent (EC50 = 87+/-14 microM) inward currents, confirming the functional incorporation to the oocyte of kainate-driven channels. Responses to kainate were consistently nondesensitizing and strongly potentiated by cyclothiazide, suggesting the selective involvement of alpha-amino-3-hydroxy-5-methyl-4isoxazolepropionate (AMPA)-preferring receptors. Binding experiments with (S)-[3H]AMPA confirmed the presence in the chick membrane preparation of low-affinity AMPA receptors (K(D) = 278 nM) amounting to <2% of the total population of kainate binding sites. A tenfold concentration of guanine nucleotides, with different degrees of phosphorylation, blocked the responses to 100 microM kainate by approximately 90%. In the case of GMP, additional concentration-inhibition studies yielded an IC50 of 180+/-11 microM. Our results illustrate the apparent failure of kainate-binding proteins to form functional channels, even when maintaining their own native membrane environment, and confirm the antagonistic behavior of guanine nucleotides, including GMP, toward glutamate receptors, in agreement with previous results of ligand-binding experiments and, more interestingly, with the marked neuroprotective effects of some guanine nucleotides in different excitotoxicity experimental paradigms.