Stable, stoichiometric delivery of diverse protein functions

As contemporary "genomics" steadily reveals an increasing number of novel gene sequences, the need for efficient methodologies to functionally characterize these genes in vivo increases significantly. Reliable coupling of target gene expression to a variety of surrogate reporter functions is critical to properly assay novel gene function in complex cell populations. Ideally, independent target and reporter proteins would be derived from a single open reading frame creating a stoichiometric relationship without obscuring subcellular localization. We report here effective strategies for assaying gene function through the stable production of chimeric polyproteins, processed intracellularly by inclusion of an intervening 19-amino-acid sequence from the 2A region of the Foot and Mouth Disease virus. Using drug-resistance and flow cytometry-based assay systems, we demonstrate that diverse protein functions are effectively delivered to various cell types by retroviral constructs as single 2A-cleaved polyproteins. For example, cells infected with a retrovirus encoding a nuclear cell cycle regulator, linked via the 2A-motif to a marker membrane protein, showed a direct correlation between cell cycle arrest and surface marker level. This demonstrates the utility of this methodology for stable and stoichiometric delivery of distinctly localized protein functionalities. In particular, the ability to exploit multiple cellular functions will serve to accelerate the functional characterization of gene products and facilitate novel gene therapy approaches.

Quantitative measurement of mast cell degranulation using a novel flow cytometric annexin-V binding assay

BACKGROUND

Mast cells are primary mediators of allergic inflammation. Antigen-mediated crosslinking of their cell surface immunoglobulin E (IgE) receptors results in degranulation and the release of proinflammatory mediators including histamine, tumor necrosis factor-alpha, and leukotrienes.

METHODS

Mast cells were stimulated to degranulate by using either IgE crosslinking or ionophore treatment. Exogenously added annexin-V was used to stain exocytosing granules, and the extent of binding was measured flow cytometrically. Release of the enzyme beta-hexosaminidase was used for population-based measurements of degranulation. Two known inhibitors of degranulation, the phosphatidylinositol 3 kinase inhibitor wortmannin and overexpression of a mutant rab3d protein, were used as controls to validate the annexin-V binding assay.

RESULTS

Annexin-V specifically bound to mast cell granules exposed after stimulation in proportion to the extent of degranulation. Annexin-V binding was calcium dependent and was blocked by phosphatidylserine containing liposomes, consistent with specific binding to this membrane lipid. Visualization of annexin-V staining showed granular cell surface patches that colocalized with the exocytic granule marker VAMP-green fluorescent protein (GFP). Wortmannin inhibited both annexin-V binding and beta-hexosaminidase release in RBL-2H3 cells, as did the expression of a dominant negative rab3d mutant protein.

CONCLUSIONS

The annexin-V binding assay represents a powerful new flow cytometric method to monitor mast cell degranulation for functional analysis.

A novel splice variant of the cell death-promoting protein BAX

Cell death plays an important role in a number of physiological processes in all complex multicellular organisms. One of the molecules that regulates this process is BAX, an integral membrane protein, that promotes apoptosis. The function of BAX is countered by BCL-2 and BCL-XL. The differential expression of these proteins can influence the ability of the cell to die or survive. In this paper, we describe the cloning, biochemical, and functional characterization of a novel splice isoform of BAX, called BAX-omega. Transient overexpression of BAX-omega protein potentiates cell death at levels comparable to that of BAX-alpha overexpression.

ralGDS family members interact with the effector loop of ras p21

Using a yeast two-hybrid system, we identified a novel protein which interacts with ras p21. This protein shares 69% amino acid homology with ral guanine nucleotide dissociation stimulator (ralGDS), a GDP/GTP exchange protein for ral p24. We designated this protein RGL, for ralGDS-like. Using the yeast two-hybrid system, we found that an effector loop mutant of ras p21 was defective in interacting with the ras p21-interacting domain of RGL, suggesting that this domain binds to ras p21 through the effector loop of ras p21. Since ralGDS contained a region highly homologous with the ras p21-interacting domain of RGL, we examined whether ralGDS could interact with ras p21. In the yeast two-hybrid system, ralGDS failed to interact with an effector loop mutant of ras p21. In insect cells, ralGDS made a complex with v-ras p21 but not with a dominant negative mutant of ras p21. ralGDS interacted with the GTP-bound form of ras p21 but not with the GDP-bound form in vitro. ralGDS inhibited both the GTPase-activating activity of the neurofibromatosis gene product (NF1) for ras p21 and the interaction of Raf with ras p21 in vitro. These results demonstrate that ralGDS specifically interacts with the active form of ras p21 and that ralGDS can compete with NF1 and Raf for binding to the effector loop of ras p21. Therefore, ralGDS family members may be effector proteins of ras p21 or may inhibit interactions between ras p21 and its effectors.

Ion effects on gating of the Ca(2+)-activated K+ channel correlate with occupancy of the pore

We studied the effects of permeant ions on the gating of the large conductance Ca(2+)-activated K+ channel from rat skeletal muscle. Rb+ blockade of inward K+ current caused an increase in the open probability as though Rb+ occupancy of the pore interferes with channel closing. In support of this hypothesis, we directly measured the occupancy of the pore by the impermeant ion Cs+ and found that it strongly correlates with its effect on gating. This is consistent with the "foot-in-the-door" model of gating, which states that channels cannot close with an ion in the pore. However, because Rb+ and Cs+ not only slow the closing rate (as predicted by the model), but also speed the opening rate, our results are more consistent with a modified version of the model in which the channel can indeed close while occupied, but the occupancy destabilizes the closed state. Increasing the occupancy of the pore by the addition of other permeant (K+ and Tl+) and impermeant (tetraethylammonium) ions did not affect the open probability. To account for this disparity, we used a two-site permeation model in which only one of the sites influenced gating. Occupancy of this "gating site" interferes with channel closing and hastens opening. Ions that directly or indirectly increase the occupancy of this site will increase the open probability.

The inactivation gate of the Shaker K+ channel behaves like an open-channel blocker

Following voltage-dependent activation, Drosophila Shaker K+ channels enter a nonconducting, inactivated state. This process has been proposed to occur by a "ball-and-chain" mechanism, in which the N-terminus of the protein behaves like a blocker tethered to the cytoplasmic side of the channel and directly occludes the pore to cause inactivation. To complement the ample evidence for the involvement of the N-terminus, we sought evidence that it blocks the pore directly. We found that inactivation exhibits several distinctive properties of pore blockade. First, recovery was speeded by increased external K+ concentrations, just as blockade can be relieved by trans-permeant ions. Second, single-channel experiments show that the channel reopens from the inactivated state upon repolarization. These openings were usually required for recovery, as though the blocking particle must exit the pore before the channel can close.

Nigrostriatal lesion alters neurophysiological responses to selective and nonselective D-1 and D-2 dopamine agonists in rat globus pallidus

The effects of the selective D-1 dopamine agonist SKF 38393, the selective D-2 agonist quinpirole, and the nonselective D-1/D-2 agonist apomorphine on spontaneous activity of globus pallidus neurons were compared in normal control rats and rats with unilateral 6-hydroxydopamine induced lesions of the nigrostriatal pathway. In control, unlesioned rats, SKF 38393 (0.4 and 10 mg/kg, i.v.) caused no significant net change in the activity of globus pallidus neurons, although some individual cells showed significant increases or decreases in discharge rates following 10 mg/kg SKF 38393 administration. In animals with unilateral 6-hydroxydopamine induced lesions, SKF 38393 caused greater increases and decreases in the discharge rates of a larger percentage of pallidal cells recorded on the ipsilateral side than in control, unlesioned animals. These rate changes were effectively reversed by the D-1 antagonist SCH 23390, but not by the D-2 antagonist YM-09151-2. Quinpirole (0.3 mg/kg, i.v.) produced modest rate increases in control, unlesioned animals and significantly larger rate increases in nigrostriatal lesioned animals. YM-09151-2, but not SCH 23390, effectively reversed quinpirole's effects in the lesioned animals. As previously reported, the nonselective D-1/D-2 agonist apomorphine (0.3 mg/kg, i.v.) produced large increases in discharge rates of pallidal cells in control, unlesioned rats. In contrast, in nigrostriatal lesioned rats, the discharge rates of some ipsilateral pallidal neurons were markedly increased, others were decreased, and some were unaffected following apomorphine administration. The dopamine antagonist spiroperidol partially to fully reversed these rate changes. In summary, apomorphine's neurophysiological profile appears to be an exaggeration of the D-1 agonist profile in the globus pallidus of these lesioned animals. The degree of change observed after apomorphine administration is consistent with results from other studies that have indicated that a synergistic interaction between effects triggered by stimulation of the two receptor subtypes can occur in these animals, as in control, unlesioned animals. However, these results further show that in rats with unilateral nigrostriatal lesions, the denervated dopamine receptors or the processes they mediate are altered so that they no longer have the requirement seen in controls for concurrent stimulation of the complementary dopamine receptor subtype for expression of the selective agonist effects.

Acute reduction of dopamine levels alters responses of basal ganglia neurons to selective D-1 and D-2 dopamine receptor stimulation

Extracellular single unit recording techniques were used to investigate dopamine agonist-induced changes in the tonic activity of globus pallidus neurons in normal control rats, and in rats in which dopamine levels were acutely reduced by alpha-methyl-para-tyrosine (AMPT) pretreatment. Systemic administration of the nonselective D-1/D-2 agonist apomorphine consistently induced large increases in the firing rates of globus pallidus neurons, as shown previously. The D-1 agonist SKF 38393 frequently induced no change in pallidal cell firing rates with doses up to 20 mg/kg; however, firing rates of 40% of the cells were stimulated by more than 20% of baseline and 14% were partially inhibited after 20 mg/kg SKF 38393. Following AMPT pretreatment, SKF 38393 induced only increases and no changes in activity; no decreases were observed. The D-2 agonist quinpirole typically increased pallidal neuron activity in a dose-dependent manner but was markedly less effective at stimulating pallidal neuron activity than apomorphine. In AMPT-treated rats, quinpirole's effects were significantly attenuated. Consistent with previous results, most cells showed large rate increases when SKF 38393 and quinpirole were coadministered to normal rats; these increases were similar in magnitude to those induced by apomorphine. In contrast to the observation that AMPT treatment altered the responses of globus pallidus neurons to individually administered quinpirole and SKF 38393, neither the increases in pallidal cell activity induced by apomorphine nor those induced by coadministration of SKF 38393 and quinpirole were significantly attenuated in AMPT-treated rats. The results support the idea that stimulation of both D-1 and D-2 receptors appears to be required to induce apomorphine-like changes in basal ganglia output. Moreover, the effects of individually administered D-1 and D-2 agonists observed in normal rats appear to depend upon the degree to which the complementary receptor subtype is stimulated by endogenous dopamine.