Darren W. Williams

Local caspase activity directs engulfment of dendrites during pruning

Pruning is important for sculpting neural circuits, as it removes excessive or inaccurate projections. Here we show that the removal of sensory neuron dendrites during pruning in Drosophila melanogaster is directed by local caspase activity. Suppressing caspase activity prevented dendrite removal, whereas a global activation of caspases within a neuron caused cell death. A new genetically encoded caspase probe revealed that caspase activity is confined to the degenerating dendrites of pruning neurons.

Cellular mechanisms of dendrite pruning in Drosophila: insights from in vivo time-lapse of remodeling dendritic arborizing sensory neurons.

Regressive events that refine exuberant or inaccurate connections are critical in neuronal development. We used multi-photon, time-lapse imaging to examine how dendrites of Drosophila dendritic arborizing (da) sensory neurons are eliminated during early metamorphosis, and how intrinsic and extrinsic cellular mechanisms control this deconstruction. Removal of the larval dendritic arbor involves two mechanisms: local degeneration and branch retraction. In local degeneration, major branch severing events entail focal disruption of the microtubule cytoskeleton, followed by thinning of the disrupted region, severing and fragmentation. Retraction was observed at distal tips of branches and in proximal stumps after severing events. The pruning program of da neuron dendrites is steroid induced; cell-autonomous dominant-negative inhibition of steroid action blocks local degeneration, although retraction events still occur. Our data suggest that steroid-induced changes in the epidermis may contribute to dendritic retraction. Finally, we find that phagocytic blood cells not only engulf neuronal debris but also attack and sever intact branches that show signs of destabilization.

Developmental architecture of adult-specific lineages in the ventral CNS of Drosophila

In Drosophila most thoracic neuroblasts have two neurogenic periods: an initial brief period during embryogenesis and a second prolonged phase during larval growth. This study focuses on the adult-specific neurons that are born primarily during the second phase of neurogenesis. The fasciculated neurites arising from each cluster of adult-specific neurons express the cell-adhesion protein Neurotactin and they make a complex scaffold of neurite bundles within the thoracic neuropils. Using MARCM clones, we identified the 24 lineages that make up the scaffold of a thoracic hemineuromere. Unlike the early-born neurons that are strikingly diverse in both form and function, the adult specific cells in a given lineage are remarkably similar and typically project to only one or two initial targets, which appear to be the bundled neurites from other lineages. Correlated changes in the contacts between the lineages in different segments suggest that these initial contacts have functional significance in terms of future synaptic partners. This paper provides an overall view of the initial connections that eventually lead to the complex connectivity of the bulk of the thoracic neurons.

Tau and tau reporters disrupt central projections of sensory neurons in Drosophila.

In this paper, the authors report that the expression of tau‐based reporter genes causes severe defects in the morphology of sensory neurons in adult Drosophila. Targeted expression of tau‐green fluorescent protein (tau‐GFP) in sensory neurons, using the galactosidase‐4 (GAL4) system, produced a range of characteristic defects in expressing neurons. The defects observed included loss of axons, abnormal axon bundling, reduced sensory arborisations, and axonal swellings (beads). Blind comparisons of adult sensory neurons labelled with tau‐GFP or CD8‐GFP showed that tau‐GFP neurons exhibited many more defects than CD8‐GFP‐expressing neurons. CD8‐GFP was found to induce no significant defects on sensory neuron morphology. Expression of tau‐lacZ and human tau in sensory neurons produced defects comparable to those seen with tau‐GFP. A developmental study showed that tau‐expressing axons grow normally and innervate the correct regions of the neuropil. The absence of these axons later in development suggests that tau‐expressing axons are lost after initial ingrowth. Examination of silver‐stained sections suggests that the absence of axons is due to axon loss rather than failure of the expression system to label the neurons. The results suggest that the expression of tau‐based reporter constructs causes severe defects in sensory neurons, resulting in degeneration. The results also indicate that Drosophila may provide a useful model system for examining the role of tau in neurodegenerative disorders. J. Comp. Neurol. 428:630–640, 2000.

Activator effect of coinjected enhancers on the muscle-specific expression of promoters in zebrafish embryos

The transient expression of reporter gene constructs in embryos provides a powerful tool to characterise cis‐acting transcriptional elements of the genes involved in development.

Mechanisms of dendritic elaboration of sensory neurons in drosophila: Insights from in vivo time lapse

In vivo time-lapse multiphoton microscopy was used to analyze the remodeling of the dendritic arborizing (da) sensory neuron known as dorsal dendritic arborizing neuron E (ddaE) during metamorphosis. After its larval processes have been removed, the cell body of ddaE repositions itself on the body wall between 25 and 40 hr after puparium formation (APF) and begins its adult outgrowth at 40 hr APF. The scaffold of the arbor is laid down between 40 and 54 hr APF, when growth is characterized by high filopodial activity at both terminal and interstitial positions and by branch retraction along with branch establishment. Later in development, filopodial activity remains high but is confined to terminal branches, and branch retraction is no longer seen. Treatment with the insect hormone juvenile hormone (JH), a key regulator of metamorphosis, alters the shape and complexity of the adult dendritic tree in a time-dependent manner. Early treatments with juvenile hormone mimic (JHm) appear to repress extension programs and maintain retraction programs. With later JHm treatments, extension programs appear normal, but retraction programs are maintained beyond their normal time. The JH treatments show the importance of retraction programs in establishing the overall arbor shape.

Role of Notch signaling in establishing the hemilineages of secondary neurons in Drosophila melanogaster.

The secondary neurons generated in the thoracic central nervous system of Drosophila arise from a hemisegmental set of 25 neuronal stem cells, the neuroblasts (NBs). Each NB undergoes repeated asymmetric divisions to produce a series of smaller ganglion mother cells (GMCs), which typically divide once to form two daughter neurons. We find that the two daughters of the GMC consistently have distinct fates. Using both loss-of-function and gain-of-function approaches, we examined the role of Notch signaling in establishing neuronal fates within all of the thoracic secondary lineages. In all cases, the ‘A’ (NotchON) sibling assumes one fate and the ‘B’ (NotchOFF) sibling assumes another, and this relationship holds throughout the neurogenic period, resulting in two major neuronal classes: the A and B hemilineages. Apparent monotypic lineages typically result from the death of one sibling throughout the lineage, resulting in a single, surviving hemilineage. Projection neurons are predominantly from the B hemilineages, whereas local interneurons are typically from A hemilineages. Although sibling fate is dependent on Notch signaling, it is not necessarily dependent on numb, a gene classically involved in biasing Notch activation. When Numb was removed at the start of larval neurogenesis, both A and B hemilineages were still generated, but by the start of the third larval instar, the removal of Numb resulted in all neurons assuming the A fate. The need for Numb to direct Notch signaling correlated with a decrease in NB cell cycle time and may be a means for coping with multiple sibling pairs simultaneously undergoing fate decisions.

Dendritic Targeting in the Leg Neuropil of Drosophila: The Role of Midline Signalling Molecules in Generating a Myotopic Map

During development of the Drosophila motor system, global guidance cues control and coordinate the targeting of both input and output elements of the neural system.

High transgene activity in the yolk syncytial layer affects quantitative transient expression assays in zebrafish (Danio rerio) embryos

For the porpose of studying the factors that cause wide variation in transient transgene expression in individual fish, alacZ reporter gene linked to a carp β-actin regulatory sequence was introduced into zebrafish embryos. As a general trend, a correlation between the number of transgene copies injected and the level of transgene expression was found. However, a substantial variation in the level of expression still occurred that could not be attributed to technical factors such as the difference in injected volume of the transgene. Co-injection of32P-dCTP and transgene into the same embryo followed by detection of β-galactosidase activity, has shown that the volume used for transgene injection, which was determined in terms of radioactivity, is not closely related to the level and location of transgene expression. Injection into the animal pole at zygote stage and the yolk cytoplasmic layer (YCL) at the 64-cell stage followed by determination of transgene expression in terms of unit injection volume, revealed that there are marked differences among tissues with regard to their capacity for transgene expression, and that the yolk syncytial layer is higher in this capacity. This high activity is assumed to be due to the high transcriptional activity or enhanced transgene replication in the syncytial layer, which is known to contain giant polyploid nuclei. The high level of expression in the YSL may influence transient expression studies using quantitative comparative analyses and should be taken into consideration when expression data are derived from homogenates of yolk sac embryos.

Persistent Larval Sensory Neurons in Adult Drosophila melanogaster

Using a combination of lineage tracing and laser ablation, we have identified a segmentally repeated array of embryonically produced sensory neurons that persist through metamorphosis into adult stages of Drosophila development. The persistent sensory neurons are found in all unfused abdominal segments, but there is segment-specific variation in the number of neurons observed. There are 12 persistent neurons in the first abdominal segment (A1), 18 in the second (A2), and 16 in segments A3-A7. Most are internal sensory neurons (dendritic arborization neurons and bipolar dendrite neurons), but two are associated with external sensilla on the sternite. All of these neurons and their axons define specific adult sensory pathways in the periphery and their locations and persistence through metamorphosis suggest a role in guiding the growth of adult sensory and motor axons.