Identification and characterization of prokineticin receptor 2 splicing variant and its modulation in an animal model of alzheimer's disease

Prokineticin 2 is a peptide that is widely distributed in the nervous system and influences a variety of brain functions, such as pain, food intake and circadian rhythms. We previously demonstrated that, in the animal model of Alzheimer’s disease, induced by the intracerebroventricular administration of Aβ1-42, there is a modulation of the prokineticin system in rat hippocampus. Prokineticin 2 is a able to mediate its signaling through two different G-protein coupled receptors, designated PKR1 and PKR2, belonging to the neuropeptide Y receptor class. These two receptors have different tissue distributions: PKR1 is expressed in diverse peripheral organs with relatively high levels in the small intestines and lung, whereas PKR2 is predominantly expressed in the central nervous system. The PKRs activate multiple intracellular signal-transduction pathways: they are Gαq-coupled receptors and promoting intracellular calcium mobilization but they also couple to Gαi (especially PKR2) and Gαs proteins. In rat hippocampus we identified a mRNA encoding for a PKR2 splice variant, that lacking the second exon, gives rise to a four-transmembrane protein denominated TM 4-7. Expression of this splicing variant in yeast, allowed us to demonstrate that TM 4-7 dimerizes with PKR2 long form and that this heterodimer binds to G protein subtypes with different specificity respect to PKR2 wild-type. Moreover we evidenced that, following Aβ1-42 intracerebroventricular injection in rat, the PKR2 hippocampal levels slightly increased respect to control animals whereas there was a strong up-regulation of the PKR2 splicing variant, TM 4-7. We showed that the increased levels of TM 4-7 determined a modulation of PKR2 signal transduction hindering STAT3 activation

The H+-ATPase purified from maize root plasma membranes retains fusicoccin in vivo activation

AbstractThe activity of ‘P-type’ ATPases is modulated through the C-terminal autoinhibitory domain. The molecular bases of this regulation are unknown. Their understanding demands functional and structural studies on the activated purified enzyme. In this paper the plasma membrane H+-ATPase from maize roots activated in vivo by fusicoccin was solubilised and fractionated by anion-exchange HPLC. Results showed that the H+-ATPase separated from fusicoccin receptors retained fusicoccin activation and that it was more evident after enzyme insertion into liposomes. These data suggest that fusicoccin stimulation does not depend on a direct action of the fusicoccin receptor on the H+-ATPase, but rather, fusicoccin brings about a permanent modification of the H+-ATPase which very likely represents a general regulatory mechanism for ‘P-type’ ATPases

Properties of Proteoliposomes Containing Fusicoccin Receptors from Maize

We have recently described a fusicoccin (FC)-sensitive system reconstituted by inserting into liposomes FC-receptors and H(+)-ATPase-enriched preparations from maize tissues. While the proteoliposomes of maize H(+)-ATPase had been already investigated, those of FC-receptors required a careful characterization before use in the dual system. In particular, the influence of the phospholipid environment on time-course, reversibility, and pH-dependence of the FC-binding reaction has been studied by comparing these properties in microsome-bound, solubilized, and liposome-entrapped receptors. Similarities and differences between the results of this investigation and those previously obtained with FC-receptors from spinach leaves suggest that functionally similar binding proteins from monocot and dicot plants have distinct structural features

Some Properties of a Functional Reconstituted Plasmalemma H(+)-ATPase Activated by Fusicoccin

Fusicoccin was shown to stimulate the ATP-driven, intravesicular acidification of liposomes reconstituted with crude fusicoccin receptors and the H(+)-translocating ATPase, both solubilized from maize (Zea mays L.) plasma membrane. The present paper reports optimal conditions for dual reconstitution and fusicoccin activation as well as the biochemical characterization of the effect of fusicoccin on this system. Fusicoccin stimulation of proton pumping was dependent on pH and fusicoccin concentration. Its specificity was demonstrated by the positive effect of two cotylenins that have a high affinity for fusicoccin receptors and by the negative response to 7,9-epideacetylfusicoccin, an inactive fusicoccin derivative. Kinetic measurements at different ATP concentrations showed that fusicoccin increases the V(max) of the enzyme. Fusicoccin stimulation of maize H(+)-ATPase was also maintained when receptors from maize were substituted by those from spinach (Spinacia oleracea L.)

Entrapment into liposomes of fusicoccin binding sites

Fusicoccin (FC) binding sites solubilised from microsomal fractions of spinach leaves have been entrapped into soybean lecithin liposomes with an 80% yield. The investigation of the properties of these proteoliposomes has demonstrated that the rates of FC-binding and of exchange between radioactive and cold FC are intermediate between those observed with membrane-bound and with solubilised binding sites. It appears that the entrapped proteins are preferentially outside-oriented since they are inactivated by trypsin treatment; moreover, Triton X-100 permeabilization of the proteoliposomes demonstrated that one fifth of these sites are inside-oriented