Boundary-driven downstep induced by syntax-prosody mapping.

This study investigates whether downstep in Japanese is directly triggered by accents. When the pitch height of a word X is lower after an accented word (A) than after an unaccented word (U), X is diagnosed as downstepped. However, this diagnosis involves two confounding factors: the already lowered F0 before X and phonological phrasing. To control these factors, this study contrasts genitive and nominative case markers and adjusts measurement points. Eight native speakers of Tokyo Japanese participated in a production experiment. The results show six key findings. First, a structure-dependent F0 downtrend was observed in UX. Second, higher F0 peaks with larger initial lowering were observed after accents with a nominative case marker compared to those with a genitive case marker, suggesting a boosting effect by boundaries. Third, larger initial lowering was observed in AX compared to UX, contradicting the notion that X is more compressed in AX due to downstep. Fourth, the paradigmatic difference in F0 height between AX and UX decreases when F0 of X is increased, supporting that boundaries trigger downstep. Fifth, downstep is not physiologically constrained but is phonologically controlled. Finally, the blocking of initial lowering in heavy syllables is not phonological but rather an articulatory phenomenon.

Graded control of Purkinje cell outputs by cAMP through opposing actions on axonal action potential and transmitter release.

All-or-none signalling by action potentials (APs) in neuronal axons is pivotal for the precisely timed and identical size of outputs to multiple distant targets. However, technical limitations with respect to measuring the signalling in small intact axons have hindered the evaluation of high-fidelity signal propagation. Here, using direct recordings from axonal trunks and/or terminals of cerebellar Purkinje cells in slice and culture, we demonstrate that the timing and amplitude of axonal outputs are gradually modulated by cAMP depending on the length of axon. During the propagation in long axon, APs were attenuated and slowed in conduction by cAMP via specifically decreasing axonal Na+ currents. Consequently, the Ca2+ influx and transmitter release at distal boutons are reduced by cAMP, counteracting its direct facilitating effect on release machinery as observed at various CNS synapses. Together, our tour de force functional dissection has unveiled the axonal distance-dependent graded control of output timing and strength by intracellular signalling. KEY POINTS: The information processing in the nervous system has been classically thought to rely on the axonal faithful and high-speed conduction of action potentials (APs). We demonstrate that the strength and timing of axonal outputs are weakened and delayed, respectively, by cytoplasmic cAMP depending on the axonal length in cerebellar Purkinje cells (PCs). Direct axonal patch clamp recordings uncovered axon-specific attenuation of APs by cAMP through reduction of axonal Na+ currents. cAMP directly augments transmitter release at PC terminals without changing presynaptic Ca2+ influx or readily releasable pool of vesicles, although the extent is weaker compared to other CNS synapses. Two opposite actions of cAMP on PC axons, AP attenuation and release augmentation, together give rise to graded control of synaptic outputs in a manner dependent on the axonal length.

Label-free DNA sensors using ultrasensitive diamond field-effect transistors in solution.

Charge detection biosensors have recently become the focal point of biosensor research, especially field-effect-transistors (FETs) that combine compactness, low cost, high input, and low output impedances, to realize simple and stable in vivo diagnostic systems. However, critical evaluation of the possibility and limitations of charge detection of label-free DNA hybridization using silicon-based ion-sensitive FETs (ISFETs) has been introduced recently. The channel surface of these devices must be covered by relatively thick insulating layers ( SiO2, Si3N4, Al2O3, or Ta2O5) to protect against the invasion of ions from solution. These thick insulating layers are not suitable for charge detection of DNA and miniaturization, as the small capacitance of thick insulating layers restricts translation of the negative DNA charge from the electrolyte to the channel surface. To overcome these difficulties, thin-gate-insulator FET sensors should be developed. Here, we report diamond solution-gate FETs (SGFETs), where the DNA-immobilized channels are exposed directly to the electrolyte solution without gate insulator. These SGFETs operate stably within the large potential window of diamond (>3.0 V). Thus, the channel surface does not need to be covered by thick insulating layers, and DNA is immobilized directly through amine sites, which is a factor of 30 more sensitive than existing Si-ISFET DNA sensors. Diamond SGFETs can rapidly detect complementary, 3-mer mismatched (10 pM) and has a potential for the detection of single-base mismatched oligonucleotide DNA, without biological degradation by cyclically repeated hybridization and denature.

A role of the C-terminus of aquaporin 4 in its membrane expression in cultured astrocytes.

BACKGROUND: Aquaporin 4 (AQP4) is a predominant water channel protein in mammalian brains, which is localized in the astrocyte plasma membrane. Membrane targeting of AQP4 is essential to perform its function. The mechanism(s) of membrane targeting is not clear in astrocytes. RESULTS: We investigated the role of the C-terminus of AQP4 (short isoform) in its membrane targeting by an expression study of C-terminal mutants of AQP4 in cultured astrocytes. The deletion of 26 C-terminal residues of AQP4 (AQP4[Delta276-301aa]) results in the intracellular localization of the protein. However, smaller deletions than 21 C-terminal residues did not alter its plasma membrane localization. These results suggest that C-terminal residues between Val(276) and Ile(280) play an important role in the expression of AQP4 in the plasma membrane. However, the plasma membrane localization of the AQP4(A(276)AAAA(280)) mutant (alanine substitution of Val(276)-Ile(280) of AQP4) suggests that another signal for membrane targeting exists in the C-terminus of AQP4. The deletion or point mutations of the PDZ binding motif of the AQP4(A(276)AAAA(280)) mutant resulted in the intracellular localization of the proteins. These results suggest that the PDZ binding motif may also be involved in the membrane targeting of AQP4. CONCLUSIONS: We found that the C-terminal sequence of AQP4 contains two important signals for membrane expression of AQP4 in cultured astrocytes. One is a hydrophobic domain and the other is a PDZ binding motif that exists in the C-terminus.