Synaptic PRG-1 modulates excitatory transmission via lipid phosphate-mediated signaling.

Plasticity related gene-1 (PRG-1) is a brain-specific membrane protein related to lipid phosphate phosphatases, which acts in the hippocampus specifically at the excitatory synapse terminating on glutamatergic neurons. Deletion of prg-1 in mice leads to epileptic seizures and augmentation of EPSCs, but not IPSCs. In utero electroporation of PRG-1 into deficient animals revealed that PRG-1 modulates excitation at the synaptic junction. Mutation of the extracellular domain of PRG-1 crucial for its interaction with lysophosphatidic acid (LPA) abolished the ability to prevent hyperexcitability. As LPA application in vitro induced hyperexcitability in wild-type but not in LPA(2) receptor-deficient animals, and uptake of phospholipids is reduced in PRG-1-deficient neurons, we assessed PRG-1/LPA(2) receptor-deficient animals, and found that the pathophysiology observed in the PRG-1-deficient mice was fully reverted. Thus, we propose PRG-1 as an important player in the modulatory control of hippocampal excitability dependent on presynaptic LPA(2) receptor signaling.

Plasticity-related gene 3 promotes neurite shaft protrusion.

BACKGROUND: Recently, we and others proposed plasticity-related gene 3 (PRG3) as a novel molecule in neuritogenesis based on PRG3 overexpression experiments in neuronal and non-neuronal cell lines. However, direct information on PRG3 effects in neuronal development and, in particular, its putative spatio-temporal distribution and conditions of action, is sparse. RESULTS: We demonstrate here that PRG3 induces filopodia formation in HEK293 cells depending on its N-glycosylation status. The PRG3 protein was strongly expressed during mouse brain development in vivo from embryonic day 16 to postnatal day 5 (E16 - P5). From P5 on, expression declined. Furthermore, in early, not yet polarized hippocampal cultured neurons, PRG3 was expressed along the neurite shaft. Knock-down of PRG3 in these neurons led to a decreased number of neurites. This phenotype is rescued by expression of an shRNA-resistant PRG3 construct in PRG3 knock-down neurons. After polarization, endogenous PRG3 expression shifted mainly to axons, specifically to the plasma membrane along the neurite shaft. These PRG3 pattern changes appeared temporally and spatially related to ongoing synaptogenesis. Therefore we tested (i) whether dendritic PRG3 re-enhancement influences synaptic currents and (ii) whether synaptic inputs contribute to the PRG3 shift. Our results rendered both scenarios unlikely: (i) PRG3 over-expression had no influence on miniature excitatory postsynaptic currents (mEPSC) and (ii) blocking of incoming signals did not alter PRG3 distribution dynamics. In addition, PRG3 levels did not interfere with intrinsic neuronal properties. CONCLUSION: Taken together, our data indicate that endogenous PRG3 promotes neurite shaft protrusion and therefore contributes to regulating filopodia formation in immature neurons. PRG3 expression in more mature neurons, however, is predominantly localized in the axon. Changes in PRG3 levels did not influence intrinsic or synaptic neuronal properties.

PRG-1 transcriptional regulation independent from Nex1/Math2-mediated activation.

Plasticity-related gene 1 (PRG-1) is a novel player in glutamatergic synaptic transmission, acting by interfering with lysophosphatidic acid (LPA)-dependent signaling pathways. In the central nervous system, PRG-1 expression is restricted to postsynaptic dendrites on glutamatergic neurons. In this study, we describe the promoter architecture of the PRG-1 gene using RNA ligase-mediated rapid amplification of cDNA ends (RLM-Race) and PCR analysis. We found that PRG-1 expression is under the control of a TATA-less promoter with multiple transcription start sites. We demonstrated also that 200-kb genomic environment of the PRG-1 gene is sufficient to mediate cell type-specific expression in a reporter mouse model. Characterization of the PRG-1 promoter resulted in the identification of a 450-bp sequence, mediating ≈40-fold enhancement of transcription in cultured primary neurons compared to controls, and which induced reporter expression in slice cultures in neurons. Recently, the regulation of PRG-1 by the basic helix-loop-helix transcription factor Nex1 (Math2, NeuroD6) was reported. However, our studies in Nex1-null-mice revealed that Nex1-deficiency induces no change in PRG-1 expression and localization. We detected an additional Nex1-independent regulation mechanism that increases PRG-1 expression and mediates neuron-specific expression in an organotypic environment.

Specific properties of sodium currents in multipotent striatal progenitor cells.

This study investigates the impact of intrinsic currents on early neural development. A rat striatal ST14A cell line immortalized by SV40 large T antigen was employed as a model system because these cells act as multipotent neural progenitors when maintained at a permissive temperature of 33 degrees C. The whole-cell patch-clamp, molecular and immunocytochemical experiments point to a unique role of sodium currents in the multipotential stage of neural development. In initial experiments, action potential-like responses were only present when multipotential ST14A cells were substantially hyperpolarized. This led us to presume that sodium channels were only recruited during deep hyperpolarization. Subsequent voltage-clamp studies confirmed a remarkably hyperpolarized steady-state inactivation of the sodium currents and also showed that the underlying channels were tetrodotoxin resistant. Direct comparison with cells whose neuronal fate was already determined, i.e. short-term cultured striatal cells isolated at embryonic day 14 and after birth (post-natal day 0), showed that both traits are unique to ST14A cells. However, sodium currents in all three groups had a fast time- and voltage-dependent activation, as well as full inactivation with roughly similar kinetics. The peculiarity in ST14A might be explained by a relative excess of heart-type Na(V)1.5 and particularly its splice variant Na(V)1.5a, as suggested by reverse transcription-polymerase chain reaction results. We conclude that multipotent neural progenitor cells express Na(+) channels in their membrane irrespective of their fate but these channels have little effect due to their subunit composition, which is regulated by alternative splicing.

Role of lipid rafts in membrane delivery of renal epithelial Na+-K+-ATPase, thick ascending limb.

Lipid rafts are cholesterol- and shingolipid-enriched membrane microdomains implicated in membrane signaling and trafficking. To assess renal epithelial raft functions through the characterization of their associated membrane proteins, we have isolated lipid rafts from rat kidney by sucrose gradient fractionation after detergent treatment. The low-density fraction was enriched in cholesterol, sphingolipid, and flotillin-1 known as lipid raft markers. Based on proteomic analysis of the low-density fraction, the protein with the highest significance score was the alpha-subunit of Na(+)-K(+)-ATPase (NKA), whose raft association was validated by simultaneous immunoblotting. The beta-subunit of NKA was copurified from the low-density fraction. To test the role of lipid rafts in sorting and membrane delivery of renal-transporting epithelia, we have chosen to study thick ascending limb (TAL) epithelium for its high NKA activity and the property to be stimulated by antidiuretic hormone (ADH). Cultured rabbit TAL cells were studied. Cholesterol depletion and detergent extraction at warmth caused a shift of NKA to the higher-density fractions. Comparative preparations from blood monocytes revealed the absence of NKA from rafts in these nonpolarized cells. Short-term exposure of rabbit TAL cells to ADH (1 h) caused translocation and enhanced raft association of NKA via cAMP activation. Preceding cholesterol depletion prevented this effect. TAL-specific, glycosylphosphatidylinositol-anchored Tamm Horsfall protein was copurified with NKA in the same raft fraction, suggesting functional interference between these products. These results may have functional implications regarding the turnover, trafficking, and regulated surface expression of NKA as the major basolateral ion transporter of TAL.

Renal effects of Tamm-Horsfall protein (uromodulin) deficiency in mice.

The Tamm-Horsfall protein (THP; uromodulin), the dominant protein in normal urine, is produced exclusively in the thick ascending limb of Henle's loop. THP mutations are associated with disease; however, the physiological role of THP remains obscure. We generated THP gene-deficient mice (THP -/-) and compared them with wild-type (WT) mice. THP -/- mice displayed anatomically normal kidneys. Steady-state electrolyte handling was not different between strains. Creatinine clearance was 63% lower in THP -/- than in WT mice (P < 0.05). Sucrose loading induced no changes between strains. However, water deprivation for 24 h decreased urine volume from 58 +/- 9 to 28 +/- 4 microl x g body wt(-1) x 24 h(-1) in WT mice (P < 0.05), whereas in THP -/- mice this decrease was less pronounced (57 +/- 4 to 41 +/- 5 microl x g body wt(-1) x 24 h(-1); P < 0.05), revealing significant interstrain difference (P < 0.05). We further used RT-PCR, Northern and Western blotting, and histochemistry to study renal transporters, channels, and regulatory systems under steady-state conditions. We found that major distal transporters were upregulated in THP -/- mice, whereas juxtaglomerular immunoreactive cyclooxygenase-2 (COX-2) and renin mRNA expression were both decreased in THP -/- compared with WT mice. These observations suggest that THP influences transporters in Henle's loop. The decreased COX-2 and renin levels may be related to an altered tubular salt load at the macula densa, whereas the increased expression of distal transporters may reflect compensatory mechanisms. Our data raise the hypothesis that THP plays an important regulatory role in the kidney.

Kidney-specific inactivation of the megalin gene impairs trafficking of renal inorganic sodium phosphate cotransporter (NaPi-IIa).

Renal reabsorption of inorganic phosphate is mediated by the type IIa sodium phosphate cotransporter (NaPi-IIa) of the proximal tubule. Changes in renal phosphate handling are mainly attributable to altered NaPi-IIa brush border membrane (BBM) expression. Parathyroid hormone (PTH) induces inactivation of NaPi-IIa by endocytic membrane retrieval and degradation. The key elements triggering this process are not clear to date. Megalin serves as a receptor for the endocytosis of multiple ligands and is coexpressed with NaPi-IIa in the proximal tubule. Investigated was the role of megalin in the regulation of NaPi-IIa in steady state and during inactivation. Kidneys and tubular BBM fractions from mice with a renal-specific megalin gene defect and from controls were analyzed by light and electron microscopic histochemical techniques and Western blot test. Steady-state levels of NaPi-IIa in BBM were significantly enhanced, mRNA levels preserved, and phosphaturia reduced in the absence of megalin. Fluid-phase endocytosis was prevented and the apical endocytic apparatus markedly reduced. Systemic administration of PTH resulted in a defective retrieval and impaired degradation of NaPi-IIa. In vitro, the application of various stimuli of the PTH-induced signaling cascade had no effect either. Adequate steady-state expression of NaPi-IIa and the capacity of the proximal tubule cell to react on PTH-driven inactivation of NaPi-IIa by endocytosis and intracellular translocation require the presence of megalin.