A resetting signal between Drosophila pacemakers synchronizes morning and evening activity

The biochemical machinery that underlies circadian rhythms is conserved among animal species and drives self-sustained molecular oscillations and functions, even within individual asynchronous tissue-culture cells. Yet the rhythm-generating neural centres of higher eukaryotes are usually composed of interconnected cellular networks, which contribute to robustness and synchrony as well as other complex features of rhythmic behaviour. In mammals, little is known about how individual brain oscillators are organized to orchestrate a complex behavioural pattern. Drosophila is arguably more advanced from this point of view: we and others have recently shown that a group of adult brain clock neurons expresses the neuropeptide PDF and controls morning activity (small LN(v) cells; M-cells), whereas another group of clock neurons controls evening activity (CRY+, PDF- cells; E-cells). We have generated transgenic mosaic animals with different circadian periods in morning and evening cells. Here we show, by behavioural and molecular assays, that the six canonical groups of clock neurons are organized into two separate neuronal circuits. One has no apparent effect on locomotor rhythmicity in darkness, but within the second circuit the molecular and behavioural timing of the evening cells is determined by morning-cell properties. This is due to a daily resetting signal from the morning to the evening cells, which run at their genetically programmed pace between consecutive signals. This neural circuit and oscillator-coupling mechanism ensures a proper relationship between the timing of morning and evening locomotor activity.     

最近邻耦合极限环振子的振幅跳跃

在不忽略极限环振子振幅变化的情况下，考察了具有自然分布的极限环振子的最近邻耦合，在过去工作的基础上，观察到了在耦合极限环振子随着耦合强度的增大而逐步同步的过程中，振子的振幅在同步分岔点处发生跳跃，并且在接近同步岔点处振幅跳跃的时间间隔加长．     

Morning and evening peaks of activity rely on different clock neurons of the Drosophila brain

In Drosophila, a 'clock' situated in the brain controls circadian rhythms of locomotor activity. This clock relies on several groups of neurons that express the Period (PER) protein, including the ventral lateral neurons (LN(v)s), which express the Pigment-dispersing factor (PDF) neuropeptide, and the PDF-negative dorsal lateral neurons (LN(d)s). In normal cycles of day and night, adult flies exhibit morning and evening peaks of activity; however, the contribution of the different clock neurons to the rest-activity pattern remains unknown. Here, we have used targeted expression of PER to restore the clock function of specific subsets of lateral neurons in arrhythmic per(0) mutant flies. We show that PER expression restricted to the LN(v)s only restores the morning activity, whereas expression of PER in both the LN(v)s and LN(d)s also restores the evening activity. This provides the first neuronal bases for 'morning' and 'evening' oscillators in the Drosophila brain. Furthermore, we show that the LN(v)s alone can generate 24 h activity rhythms in constant darkness, indicating that the morning oscillator is sufficient to drive the circadian system.     

Learning and memory mutations impair acoustic priming of mating behaviour in Drosophila

The courtship song in Drosophila melanogaster has two components, a low-frequency hum and a train of pulses with a species-specific interpulse interval (IPI) of 30-40 ms(1,2). The IPIs oscillate rhythmically, with periods between 50 and 60 s in wild-type males(3). When females are stimulated with artificial songs in the presence of courting but silent (wingless) males, the 'pulse song' and its oscillation can enhance mating success(4?6). If separated males and females are first simultaneously primed with invariant 34-ms IPIs, their subsequent mating success is improved(7). However, exclusive prestimulation of females leads to faster mating only when the hum component of the song is applied, not constant 34-ms IPIs(5). We have re-examined these findings by testing whether prior exposure of females to a rhythmic pulse song speeds up subsequent mating performance. We report here that it does. Furthermore, learning and memory mutations(8), expressed in the females to whom songs are being played, either 'block' or attenuate the effectiveness of acoustical priming.     

Maternal control of Drosophila segmentation gene expression

Several genes have been identified that are involved in establishing the segmented body pattern during development of the fruit-fly Drosophila melanogaster. These fall into several classes on the basis of the kind of alteration to the wild-type segmentation pattern observed in mutant embryos. For example, mutations of the pair-rule class, such as fushi tarazu (ftz), cause the deletion of pattern elements with a two-segment periodicity; those of the gap class, such as knirps, cause the deletion of contiguous groups of segments. The availability of antibodies against the ftz protein has allowed its spatial pattern of expression to be studied during the development of wild-type and mutant embryos. The aim of the latter kind of experiment is to investigate possible interactions between these important genes. We have recently reported that knirps mutations cause a striking alteration to the pattern of transverse stripes of ftz expression usually seen during embryogenesis. Knirps is a zygotically-expressed gene, but recently a class of maternally-active genes has been identified that causes similar defects in pattern formation. We have now investigated the pattern of ftz expression in mutants of this class and have found that while they do have features seen in knirps mutants, they also exhibit significant differences between the different mutations reflecting the distinct but overlapping domains of gene activity. These observations demonstrate that maternally-active segmentation genes regulate zygotic gene expression, and that some of their effects on ftz may be directed through the knirps gene.     

Genetic control and evolution of sexually dimorphic characters in Drosophila

Sexually dimorphic abdominal pigmentation and segment morphology evolved recently in the melanogaster species group of the fruitfly Drosophila. Here we show that these traits are controlled by the bric à brac [corrected] (bab) gene, which integrates regulatory inputs from the homeotic and sex-determination pathways. bab expression is modulated segment- and sex-specifically in sexually dimorphic species, but is uniform in sexually monomorphic species. We suggest that bab has an ancestral homeotic function, and that regulatory changes at the bab locus played a key role in the evolution of sexual dimorphism. Pigmentation patterns specified by bab affect mating preferences, suggesting that sexual selection has contributed to the evolution of bab regulation.     

小尺寸恒温晶体振荡器控温系统设计

对比分析了小尺寸OCXO恒温槽与传统OCXO恒温槽温度特性的差别，以及由此而引起的问题。根据主要影响因素，提出了温度补偿算法。基于该算法，设计了一种适用于小尺寸OCXO的温度控制系统。经实践证明，采用该方法可以大大提高小尺寸OCXO频率温度特性。     

The behaviour of Drosophila adult hindgut stem cells is controlled by Wnt and Hh signalling

The intestinal tract maintains proper function by replacing aged cells with freshly produced cells that arise from a population of self-renewing intestinal stem cells (ISCs). In the mammalian intestine, ISC self renewal, amplification and differentiation take place along the crypt-villus axis, and are controlled by the Wnt and hedgehog (Hh) signalling pathways. However, little is known about the mechanisms that specify ISCs within the developing intestinal epithelium, or about the signalling centres that help maintain them in their self-renewing stem cell state. Here we show that in adult Drosophila melanogaster, ISCs of the posterior intestine (hindgut) are confined to an anterior narrow segment, which we name the hindgut proliferation zone (HPZ). Within the HPZ, self renewal of ISCs, as well as subsequent proliferation and differentiation of ISC descendants, are controlled by locally emanating Wingless (Wg, a Drosophila Wnt homologue) and Hh signals. The anteriorly restricted expression of Wg in the HPZ acts as a niche signal that maintains cells in a slow-cycling, self-renewing mode. As cells divide and move posteriorly away from the Wg source, they enter a phase of rapid proliferation. During this phase, Hh signal is required for exiting the cell cycle and the onset of differentiation. The HPZ, with its characteristic proliferation dynamics and signalling properties, is set up during the embryonic phase and becomes active in the larva, where it generates all adult hindgut cells including ISCs. The mechanism and genetic control of cell renewal in the Drosophila HPZ exhibits a large degree of similarity with what is seen in the mammalian intestine. Our analysis of the Drosophila HPZ provides an insight into the specification and control of stem cells, highlighting the way in which the spatial pattern of signals that promote self renewal, growth and differentiation is set up within a genetically tractable model system.     

Chemical codes for the control of behaviour in arthropods

Neuromodulators and hormones elicit and modify well-defined behaviours. Their mode of action can be studied to advantage in arthropods, where the natural releasing cells and neuronal target circuits are concisely identified. The coordinated actions of biogenic amines and peptides on both central and peripheral neural activity and metabolic processes bias the whole organism to perform a coherent behavioural routine.     

A single population of olfactory sensory neurons mediates an innate avoidance behaviour in Drosophila

All animals exhibit innate behaviours in response to specific sensory stimuli that are likely to result from the activation of developmentally programmed neural circuits. Here we observe that Drosophila exhibit robust avoidance to odours released by stressed flies. Gas chromatography and mass spectrometry identifies one component of this 'Drosophila stress odorant (dSO)' as CO2. CO2 elicits avoidance behaviour, at levels as low as 0.1%. We used two-photon imaging with the Ca2+-sensitive fluorescent protein G-CaMP to map the primary sensory neurons governing avoidance to CO2. CO2 activates only a single glomerulus in the antennal lobe, the V glomerulus; moreover, this glomerulus is not activated by any of 26 other odorants tested. Inhibition of synaptic transmission in sensory neurons that innervate the V glomerulus, using a temperature-sensitive Shibire gene (Shi(ts)), blocks the avoidance response to CO2. Inhibition of synaptic release in the vast majority of other olfactory receptor neurons has no effect on this behaviour. These data demonstrate that the activation of a single population of sensory neurons innervating one glomerulus is responsible for an innate avoidance behaviour in Drosophila.     

Dynamic control of positional information in the early Drosophila embryo

Morphogen gradients contribute to pattern formation by determining positional information in morphogenetic fields. Interpretation of positional information is thought to rely on direct, concentration-threshold-dependent mechanisms for establishing multiple differential domains of target gene expression. In Drosophila, maternal gradients establish the initial position of boundaries for zygotic gap gene expression, which in turn convey positional information to pair-rule and segment-polarity genes, the latter forming a segmental pre-pattern by the onset of gastrulation. Here we report, on the basis of quantitative gene expression data, substantial anterior shifts in the position of gap domains after their initial establishment. Using a data-driven mathematical modelling approach, we show that these shifts are based on a regulatory mechanism that relies on asymmetric gap-gap cross-repression and does not require the diffusion of gap proteins. Our analysis implies that the threshold-dependent interpretation of maternal morphogen concentration is not sufficient to determine shifting gap domain boundary positions, and suggests that establishing and interpreting positional information are not independent processes in the Drosophila blastoderm.     

高精度高性能晶体振荡器电路

设计了一种用于实时时钟的高精度高性能晶体振荡器.采用振幅控制机理以达到高频率稳定性和低功耗的要求,基于外部电容调谐的原理来进一步提高实时时钟精度.电路在0.6μm CMOS工艺上实现,测试结果表明在工作电压为3 V的条件下,振荡器的工作电流小于240 nA,振荡器能够稳定工作在1.5~5.5 V的电压范围,时钟精度可达5.8×10-6.     

晨练健身过程中存在的问题及对策研究

从可能影响健康晨练的主要因素入手,科学地进行调查研究,综合分析晨练过程中存在的普遍问题,探究晨练者对于晨练的认识程度,为如何科学进行晨练提供理论支持．