The combination of immunofluorescence and laser scanning confocal microscopy (LSM) is essential to high-resolution detection of molecular distribution in biological specimens. A frequent limitation is the need to image deep inside a tissue or in a specific plane, which may be inaccessible due to tissue size or shape. Recreating high-resolution 3D images is not possible because the point-spread function of light reduces the resolution in the Z-axis about 3-fold, compared to XY, and light scattering obscures signal deep in the tissue. However, the XY plane of interest can be chosen if embedded samples are precisely oriented and sectioned prior to imaging (Figure 1). Here we describe the preparation of frozen tissue sections of the Drosophila wing imaginal disc, which allows us to obtain high-resolution images throughout the depth of this folded epithelium.


Figure 1. The epithelial structure and undistorted folding pattern are revealed in its entire depth in this frozen section of developing Drosophila wing. A-D. Transverse dorsoventral sections through the wing pouch. A. Cryosection reveals nuclei (A, green) and subcellular distribution of α-catenin (A’, A”, magenta) with signal throughout the depth of the epithelium. The basal surface is clearly detectable (arrows). A” is digitally enhanced image of A’. B. A Z-stack of images collected in a top-down view displayed as XZ orthogonal view reveals nuclei (B) but little discernable detail for α-catenin (B’, B”) and even the digitally enhanced image (B”) fails to reveal the basal epithelial surface (arrow). C. Transverse dorsoventral section displaying the Distal-less (Dll, green) gradient in the wing pouch and subcellular localization of DE-Cadherin (magenta) throughout the epithelium. D. View of the wing pouch. Dorsal is to the left; apical is up. Scale bars are 1 µm in A, B, 11 µm in C, 5 µm in D.

Axonal transport, which is composed of microtubules, motor proteins and a variety of types of cargo, is a prominent feature of neurons. Monitoring these molecular dynamics is important to understand the biological processes of neurons as well as neurodegenerative disorders that are associated with axonal dysfunction. Here, we describe a protocol for monitoring the axonal transport of motor neurons in Drosophila larvae using inverted fluorescence microscopy.

We recently reported an Affinity-directed PROtein Missile (AdPROM) system for the targeted proteolysis of endogenous proteins of interest (POI) (Fulcher et al., 2016 and 2017). AdPROM consists of the Von Hippel Lindau (VHL) protein, a Cullin 2 E3 ligase substrate receptor (Bosu and Kipreos, 2008), conjugated to a high affinity polypeptide binder (such as a camelid nanobody) that recognises the target protein in cells. When introduced in cells, the target protein is recruited to the CUL2 E3 ubiquitin ligase complex for ubiquitin-mediated proteasomal degradation. For target protein recruitment, we have utilised both camelid-derived VHH domain nanobodies as well as synthetic polypeptide monobodies based on the human type III fibronectin domain (Sha et al., 2013; Fridy et al., 2014; Schmidt et al., 2016). In this protocol, we describe detailed methodology involved in generating AdPROM constructs and their application in human cell lines for target protein destruction. AdPROM allows functional characterisation of the POI and its efficiency of target protein destruction overcomes many limitations of RNA-interference approaches, which necessitate long treatments and are associated with off-target effects, and CRISPR/Cas9 gene editing, which is not always feasible.

We have developed locus-specific chromatin immunoprecipitation (locus-specific ChIP) technologies consisting of insertional ChIP (iChIP) and engineered DNA-binding molecule-mediated ChIP (enChIP). Locus-specific ChIP is a method to isolate a genomic region of interest from cells while it also identifies what binds to this region using mass spectrometry (for protein) or next generation sequencing (for RNA or DNA) as described in Fujita et al. (2016a). Recently, we identified genomic regions that physically interact with a locus using an updated form of enChIP, in vitro enChIP, in combination with NGS (in vitro enChIP-Seq) (Fujita et al., 2017a). Here, we describe a protocol on in vitro enChIP to isolate a target locus for identification of genomic regions that physically interact with the locus.

Neuronal electrical properties are often aberrant in neurological disorders. Human induced pluripotent stem cells (hiPSCs)-derived neurons represent a useful platform for neurological disease modeling, drug discovery and toxicity screening in vitro. Multi-electrode array (MEA) systems offer a non-invasive and label-free platform to record neuronal evoked-responses concurrently from multiple electrodes. To better detect the neural network changes, we used the Axion Maestro MEA platform to assess neuronal activity and bursting behaviors in hiPSC-derived neuronal cultures. Here we describe the detailed protocol for neuronal culture preparation, MEA recording, and data analysis, which we hope will benefit other researchers in the field.

The intestine is a central organ required for the digestion of food, the absorption of nutrients and for fighting against aggressors ingested along with the food. Impairment of gut physiology following mucosal damages impacts its digestive capacities that consequently will affect growth, wellbeing or even survival of the individual. Hence, the assessment of intestinal functions encompasses, among others, the monitoring of its integrity, its cellular renewing, its immune defenses, the production of enteroendocrine hormones and its digestive capacities. Here, we describe in detail how to assess the activity of the proteases secreted in the intestinal lumen of adult Drosophila melanogaster flies. This method can also be used for larval intestines. The present protocol is adapted and improved from the Sigma-Aldrich’s protocol proposed in the ‘Protease Fluorescent Detection Kit’ (Product code PF0100).

Fecal sampling is a non-invasive method which raises the possibility to study the development and the changes in the microbial community throughout different time points of a fly population or throughout different treatments. This method allows precise manipulation to trigger the fly’s physiology by nutritional interventions, bacterial infections or other stressors.

As in most other animals, the intestinal microbiota is essential for a healthy fly-life. Because Drosophila only harbors a relative simple bacterial community with a small variety of round about 8 to 10 different species, it is rather easy to build up the microbial community and to investigate microbial changes after treatment.

Another positive effect using the fly’s feces is that bacteria that are not part of the intestinal microbiome, for example Wolbachia, can be excluded directly from the analysis because they are not excreted.

Using this method, the generated datasets may reflect a good paradigm to study microbiome associated diseases in a simple fly model or furthermore, to test drugs in a high-throughput approach.

Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) and CRISPR-associated (Cas) systems function as an adaptive immune system in bacteria and archaea for defense against invading viruses and plasmids (Barrangou and Marraffini, 2014). The effector nucleases from some class 2 CRISPR-Cas systems have been repurposed for heterologous targeting in eukaryotic cells (Jinek et al., 2012; Cong et al., 2013; Mali et al., 2013; Zetsche et al., 2015). However, the genomic environments of eukaryotes are distinctively different from that of prokaryotes in which CRISPR-Cas systems have evolved. Mammalian heterochromatin was found to be a barrier to target DNA access by Streptococcus pyogenes Cas9 (SpCas9), and nucleosomes, the basic units of the chromatin, were also found to impede target DNA access and cleavage by SpCas9 in vitro (Knight et al., 2015; Hinz et al., 2015; Horlbeck et al., 2016; Isaac et al., 2016). Moreover, many CRISPR-Cas systems characterized to date often exhibit inactivity in mammalian cells and are thus precluded from gene editing applications even though they are active in bacteria or on purified DNA substrates. Thus, there is a need to devise a means to alleviate chromatin inhibition to increase gene editing efficiency, especially on difficult-to-access genomic sites, and to enable use of otherwise inactive CRISPR-Cas nucleases for gene editing need. Here we describe a proxy-CRISPR protocol for restoring nuclease activity of various class 2 CRISPR-Cas nucleases on otherwise inaccessible genomic sites in human cells via proximal targeting of a catalytically dead Cas9 (Chen et al., 2017). This protocol is exemplified here by using Campylobacter jejuni Cas9 (CjCas9) as nuclease and catalytically dead SpCas9 (SpdCas9) as proximal DNA binding protein to enable CjCas9 to cleave the target for gene editing using single stranded DNA oligo templates.

The complexity surrounding presynaptic recordings in mammals is a significant barrier to the study of presynaptic mechanisms during neurotransmission in the mammalian central nervous system (CNS). Here we describe an adult fly neuromuscular junction (NMJ), the ciberial muscle 9 (CM9) NMJ, which allows for the recording of both evoked (EPSPs) and spontaneous postsynaptic excitatory potentials (mEPSPs) at a mature glutamatergic synapse. Combined with CM9-specific genetic technologies, the CM9 NMJ provides a powerful experimental system to better understand the regulation of neurotransmitter release at a mature synapse.

To investigate cellular, molecular and behavioral mechanisms of noxious cold detection, we developed cold plate behavioral assays and quantitative means for evaluating the predominant noxious cold-evoked contraction behavior. To characterize neural activity in response to noxious cold, we implemented a GCaMP6-based calcium imaging assay enabling in vivo studies of intracellular calcium dynamics in intact Drosophila larvae. We identified Drosophila class III multidendritic (md) sensory neurons as multimodal sensors of innocuous mechanical and noxious cold stimuli and to dissect the mechanistic bases of multimodal sensory processing we developed two independent functional assays. First, we developed an optogenetic dose response assay to assess whether levels of neural activation contributes to the multimodal aspects of cold sensitive sensory neurons. Second, we utilized CaMPARI, a photo-switchable calcium integrator that stably converts fluorescence from green to red in presence of high intracellular calcium and photo-converting light, to assess in vivo functional differences in neural activation levels between innocuous mechanical and noxious cold stimuli. These novel assays enable investigations of behavioral and functional roles of peripheral sensory neurons and multimodal sensory processing in Drosophila larvae.