dTBI2: A Calibrated, Tunable Device for Administering Traumatic Brain Injury in Drosophila.

The second-generation Drosophila traumatic brain injury (TBI) device dTBI2 improves Drosophila TBI administration by providing a moderate-throughput, tunable, head-specific injury. Our updated device design improves user-friendliness, eliminates inconsistencies in injury timing, and has an updated circuit design to extend the longevity of delicate electronic components. dTBI2 improves reproducibility across users and runs, and results in more consistent post-injury phenotypes. This protocol describes the construction, calibration, and use of the dTBI2 device, which uses an Arduino-controlled piezoelectric actuator to deliver a force that compresses a fly head against a metal collar. The duration and depth of head compression is tunable, allowing calibration of injury severity. All device components are commercially available, and the entire device can be constructed in under a week for less than $1000. The dTBI2 design will enable any lab to build a highly reliable, low-cost device for Drosophila TBI, facilitating increased adoption and ease of exploration of closed-head TBI in Drosophila for forward genetic screens. We describe below the three protocols necessary for constructing a dTBI2 device. © 2024 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Construction of the dTBI2 control device Basic Protocol 2: Construction of the piezoelectric actuator housing Basic Protocol 3: Administration of dTBI2 injuries.

Drosophila clock cells use multiple mechanisms to transmit time-of-day signals in the brain.

Regulation of circadian behavior and physiology by the Drosophila brain clock requires communication from central clock neurons to downstream output regions, but the mechanism by which clock cells regulate downstream targets is not known. We show here that the pars intercerebralis (PI), previously identified as a target of the morning cells in the clock network, also receives input from evening cells. We determined that morning and evening clock neurons have time-of-day-dependent connectivity to the PI, which is regulated by specific peptides as well as by fast neurotransmitters. Interestingly, PI cells that secrete the peptide DH44, and control rest:activity rhythms, are inhibited by clock inputs while insulin-producing cells (IPCs) are activated, indicating that the same clock cells can use different mechanisms to drive cycling in output neurons. Inputs of morning cells to IPCs are relevant for the circadian rhythm of feeding, reinforcing the role of the PI as a circadian relay that controls multiple behavioral outputs. Our findings provide mechanisms by which clock neurons signal to nonclock cells to drive rhythms of behavior.

The Drosophila copper transporter Ctr1C functions in male fertility.

Living organisms have evolved intricate systems to harvest trace elements from the environment, to control their intracellular levels, and to ensure adequate delivery to the various organs and cellular compartments. Copper is one of these trace elements. It is at the same time essential for life but also highly toxic, not least because it facilitates the generation of reactive oxygen species. In mammals, copper uptake in the intestine and copper delivery into other organs are mediated by the copper importer Ctr1. Drosophila has three Ctr1 homologs: Ctr1A, Ctr1B, and Ctr1C. Earlier work has shown that Ctr1A is an essential gene that is ubiquitously expressed throughout development, whereas Ctr1B is responsible for efficient copper uptake in the intestine. Here, we characterize the function of Ctr1C and show that it functions as a copper importer in the male germline, specifically in maturing spermatocytes and mature sperm. We further demonstrate that loss of Ctr1C in a Ctr1B mutant background results in progressive loss of male fertility that can be rescued by copper supplementation to the food. These findings hint at a link between copper and male fertility, which might also explain the high Ctr1 expression in mature mammalian spermatozoa. In both mammals and Drosophila, the X chromosome is known to be inactivated in the male germline. In accordance with such a scenario, we provide evidence that in Drosophila, the autosomal Ctr1C gene originated as a retrogene copy of the X-linked Ctr1A, thus maintaining copper delivery during male spermatogenesis.

Regulation of epidermal growth factor receptor trafficking by lysine deacetylase HDAC6.

Binding of epidermal growth factor (EGF) to its receptor leads to receptor dimerization, assembly of protein complexes, and activation of signaling networks that control key cellular responses. Despite their fundamental role in cell biology, little is known about protein complexes associated with the EGF receptor (EGFR) before growth factor stimulation. We used a modified membrane yeast two-hybrid system together with bioinformatics to identify 87 candidate proteins interacting with the ligand-unoccupied EGFR. Among them was histone deacetylase 6 (HDAC6), a cytoplasmic lysine deacetylase, which we found negatively regulated EGFR endocytosis and degradation by controlling the acetylation status of alpha-tubulin and, subsequently, receptor trafficking along microtubules. A negative feedback loop consisting of EGFR-mediated phosphorylation of HDAC6 Tyr(570) resulted in reduced deacetylase activity and increased acetylation of alpha-tubulin. This study illustrates the complexity of the EGFR-associated interactome and identifies protein acetylation as a previously unknown regulator of receptor endocytosis and degradation.

Examining protein protein interactions using endogenously tagged yeast arrays: the cross-and-capture system.

Comprehensive approaches to detect protein-protein interactions (PPIs) have been most successful in the yeast model system. Here we present "Cross-and-Capture," a novel assay for rapid, sensitive assessment of PPIs via pulldown of differently tagged yeast strain arrays. About 500 yeast genes that function in DNA replication, repair, and recombination and nuclear proteins of unknown function were chromosomally tagged with six histidine residues or triple VSV epitopes. We demonstrate that the assay can interrogate a wide range of previously known protein complexes with increased resolution and sensitivity. Furthermore, we use "Cross-and-Capture" to identify two novel protein complexes: Rtt101p-Mms1p and Sae2p-Mre11p. The Rtt101p-Mms1p interaction was subsequently characterized by genetic and functional analyses. Our studies establish the "Cross-and-Capture" assay as a novel, versatile tool that provides a valuable complement for the next generation of yeast proteomic studies.

In vivo construction of transgenes in Drosophila.

Transgenic flies are generated by transposon-mediated transformation. A drawback of this approach is the size limit of transposable elements. Here, we propose a novel method that allows the extension of transgenes in vivo. This method is based on an incomplete transgene that has been constructed in vitro and integrated into the Drosophila genome by conventional transgenesis. The incomplete transgene contains two short stretches of DNA homologous to the 5'- and 3'-ends of a larger DNA segment of interest. Between the short stretches of homology an I-SceI recognition site is located. Once activated, I-SceI endonuclease introduces a DNA double-strand break, which triggers ectopic recombination between the stretches of homology and the endogenous locus. Through gap repair, the transgene obtains the complete region of interest in vivo. Our results show that this method is effective for copying up to 28 kb of genomic DNA into the transgene, thereby eliminating the technical difficulties associated with the in vitro construction of large transgenes and extending the size limits of current transgenesis protocols. In general, this method may be a useful technique for genetic engineering of eukaryotic model organisms.

Evidence standards in experimental and inferential INSDC Third Party Annotation data.

The Third Party Annotation (TPA) project collects and presents high-quality annotation of nucleotide sequence. Annotation is submitted by researchers who have not themselves generated novel nucleotide sequence. In its first few years, the resource has proven to be popular with submitters from a range of biological research areas. Central to the project is the requirement for high-quality data, resulting from experimental and inferred analysis discussed in peer-reviewed publications. The data are divided into two tiers: those with experimental evidence and those with inferential evidence. Standards for TPA are detailed and illustrated with the aid of case studies.

Application of the split-ubiquitin membrane yeast two-hybrid system to investigate membrane protein interactions.

The characterization of protein-protein interactions provides the foundation for further studies concerning protein complex function and regulation. Since the advent of the yeast two-hybrid assay, many additional genetic systems based upon the principle of protein fragment complementation have been designed. One such system, the split-ubiquitin membrane yeast two-hybrid system (MbYTH), is able to analyze the interaction status between two integral membrane proteins. This ability of the MbYTH system augments genetic analysis of protein interactions by covering for the inherent limitation of the yeast two-hybrid system when studying membrane protein interactions. Herein, we provide a description of the MbYTH method and detailed protocols in order to monitor protein interactions and discover novel interacting partners using the MbYTH system.

Yeast genetic methods for the detection of membrane protein interactions: potential use in drug discovery.

Due to the pivotal role of membrane proteins in many cellular processes, their direct link to human disease and their often extracellular accessibility towards drugs, an understanding of membrane protein function is desirable. However, the hydrophobic nature of membrane proteins often results in insoluble proteins which makes protein isolation difficult and therefore hinders the determination of protein complex composition and protein function. Recently, several yeast genetic techniques have made the characterisation of interactions among membrane proteins more feasible. Techniques such as the guanine-nucleotide binding protein fusion assay, the reverse Ras recruitment system and the split-ubiquitin system have been fruitful in monitoring known protein interactions and uncovering novel interactions. Since many disease states have altered membrane protein function, one can use these systems to recreate interactions involving disease causing membrane proteins. Once established, screens for small molecules, peptides and/or single chain antibodies which disrupt such interactions can provide insight into the biology of the interaction and thus help guide therapeutical research. In this review, we speculate on the feasibility of using inhibitors of protein interactions as drugs and the adaptation of these techniques to select for inhibitors of defined protein interactions.

Scabrous and Gp150 are endosomal proteins that regulate Notch activity.

Notch and Delta are required for lateral inhibition during eye development. They prevent a tenfold excess in R8 photoreceptor cell specification. Mutations in two other genes, Scabrous and Gp150, result in more modestly increased R8 specification. Their roles in Notch signaling have been unclear. Both sca and gp150 are required for ectopic Notch activity that occurs in the split mutant. Similar phenotypes showed that sca and gp150 genes act in a common pathway. Gp150 was required for all activities of Sca, including inhibition of Notch activity and association with Notch-expressing cells that occur when Sca is ectopically expressed. Mosaic analysis found that the gp150 and sca genes were required in different cells from one another. Gp150 concentrated Sca protein in late endosomes. A model is proposed in which endosomal Sca and Gp150 promote Notch activation in response to Delta, by regulating acquisition of insensitivity to Delta in a subset of cells.

Drosophila Gp150 is required for early ommatidial development through modulation of Notch signaling.

Cellular signaling activities must be tightly regulated for proper cell fate control and tissue morphogenesis. Here we report that the Drosophila leucine-rich repeat transmembrane glycoprotein Gp150 is required for viability, fertility and development of the eye, wing and sensory organs. In the eye, Gp150 plays a critical role in regulating early ommatidial formation. Gp150 is highly expressed in cells of the morphogenetic furrow (MF) region, where it accumulates exclusively in intracellular vesicles in an endocytosis-independent manner. Loss of gp150 function causes defects in the refinement of photoreceptor R8 cells and recruitment of other cells, which leads to the formation of aberrant ommatidia. Genetic analyses suggest that Gp150 functions to modulate Notch signaling. Consistent with this notion, Gp150 is co-localized with Delta in intracellular vesicles in cells within the MF region and loss of gp150 function causes accumulation of intracellular Delta protein. Therefore, Gp150 might function in intracellular vesicles to modulate Delta-Notch signaling for cell fate control and tissue morphogenesis.