Brain-specific lipoprotein receptors interact with astrocyte derived apolipoprotein and mediate neuron-glia lipid shuttling

Yin, Jun; Spillman, Emma; Cheng, Ethan S.; Short, Jacob; Chen, Yang; Lei, Jingce; Gibbs, Mary B.; Rosenthal, Justin; Chen, Sheng Di; Chen, Yuki X.; Veerasammy, Kelly; Choetso, Tenzin; Abzalimov, Rinat R.; Wang, Bei; Han, Chun; He, Ye; Yuan, Quan

doi:10.1038/s41467-021-22751-7

Cited by 31 publications

(35 citation statements)

References 84 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In this respect, the hypothesis of ApoD working on oxidized lipid "whiskers" (Greenberg et al, 2008;Del Caño-Espinel, 2014) on cell membrane bilayers or lipoparticles is appealing and worth contrasting. 6) Recent studies on a Drosophila homolog (Yin et al, 2021) point to lipid droplets as another higher-order lipid structure susceptible to be modulated by ApoD. Searching for lipid droplet-managing functions of vertebrate ApoD is therefore pertinent.…”

Section: Future Goals For Apod Biologymentioning

confidence: 99%

The Lipocalin Apolipoprotein D Functional Portrait: A Systematic Review

Sánchez

Ganfornina

2021

Front. Physiol.

View full text Add to dashboard Cite

Apolipoprotein D is a chordate gene early originated in the Lipocalin protein family. Among other features, regulation of its expression in a wide variety of disease conditions in humans, as apparently unrelated as neurodegeneration or breast cancer, have called for attention on this gene. Also, its presence in different tissues, from blood to brain, and different subcellular locations, from HDL lipoparticles to the interior of lysosomes or the surface of extracellular vesicles, poses an interesting challenge in deciphering its physiological function: Is ApoD a moonlighting protein, serving different roles in different cellular compartments, tissues, or organisms? Or does it have a unique biochemical mechanism of action that accounts for such apparently diverse roles in different physiological situations? To answer these questions, we have performed a systematic review of all primary publications where ApoD properties have been investigated in chordates. We conclude that ApoD ligand binding in the Lipocalin pocket, combined with an antioxidant activity performed at the rim of the pocket are properties sufficient to explain ApoD association with different lipid-based structures, where its physiological function is better described as lipid-management than by long-range lipid-transport. Controlling the redox state of these lipid structures in particular subcellular locations or extracellular structures, ApoD is able to modulate an enormous array of apparently diverse processes in the organism, both in health and disease. The new picture emerging from these data should help to put the physiological role of ApoD in new contexts and to inspire well-focused future research.

show abstract

Section: Future Goals For Apod Biologymentioning

confidence: 99%

The Lipocalin Apolipoprotein D Functional Portrait: A Systematic Review

Sánchez

Ganfornina

2021

Front. Physiol.

View full text Add to dashboard Cite

show abstract

“…Moreover, optogenetic/chemogenetic and calcium imaging techniques have been combined with trans-Tango to understand the functional connectivity between preand postsynaptic neurons (Guo et al, 2018;He et al, 2019;Feng et al, 2020). TRACT has been used to label postsynaptic neurons in olfactory and rhythm circuits (Huang et al, 2017), as well as glial cells (Yin et al, 2021). BAcTrace has been applied to show synaptic connections from olfactory projection neurons to olfactory receptor neurons and Kenyon cells of mushroom bodies and lateral horn neurons (Cachero et al, 2020).…”

Section: Applications Of Genetic Transsynaptic Toolsmentioning

confidence: 99%

Genetic Transsynaptic Techniques for Mapping Neural Circuits in Drosophila

2021

Front. Neural Circuits

View full text Add to dashboard Cite

A neural circuit is composed of a population of neurons that are interconnected by synapses and carry out a specific function when activated. It is the structural framework for all brain functions. Its impairments often cause diseases in the nervous system. To understand computations and functions in a brain circuit, it is of crucial importance to identify how neurons in this circuit are connected. Genetic transsynaptic techniques provide opportunities to efficiently answer this question. These techniques label synapses or across synapses to unbiasedly label synaptic partners. They allow for mapping neural circuits with high reproducibility and throughput, as well as provide genetic access to synaptically connected neurons that enables visualization and manipulation of these neurons simultaneously. This review focuses on three recently developed Drosophila genetic transsynaptic tools for detecting chemical synapses, highlights their advantages and potential pitfalls, and discusses the future development needs of these techniques.

show abstract

“…The copyright holder for this this version posted November 11, 2021. ; https://doi.org/10.1101/2021.11.10.467940 doi: bioRxiv preprint morphogenesis and function, and future studies should address its interaction with other pathways involved in these processes. [11] shows that a short isoform of LpR1 (LpR1G) interacts with the lipocalin Glaz. Interestingly, a report from the Bellen group shows that the transport of lipids between neurons and glia is mediated by Glaz and neural lazarillo proteins (Nlaz), the orthologs for ApoD in flies [82].…”

Section: Lprs Are Required For Adult Mb Structure and Operationmentioning

confidence: 99%

“…Moreover, in the case of LpR1, this effect depends on the short isoforms. Specifically, it was reported that knocking down a specific LpR1 short isoform (LpR1G) or LpR2 in LNv reduces activity-dependent dendrite arborization [11,12]. Since a genome-wide RNAi screen in cultured neurons from D. melanogaster embryos identified LpR2 as a gene implicated in neuronal development [13] and given the fact that LpR1 and LpR2 are widely expressed in the Drosophila larval brain [11,12], it is possible to propose that LpRs could contribute to the development, maturation and operation of several fly brain regions.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Lipophorin receptors regulate mushroom bodies development and participate in learning, memory and sleep in flies

Rojo-Cortés

Tapia-Valladares

Fuenzalida‐Uribe

et al. 2021

Preprint

View full text Add to dashboard Cite

BackgroundDrosophila melanogaster Lipophorin Receptors (LpRs), LpR1 and LpR2, mediate lipid uptake. The orthologs of these receptors in vertebrates, ApoER2 and VLDL-R, bind Reelin, a glycoprotein not present in flies. These receptors are associated with the development and function of the hippocampus and cerebral cortex, important association areas in the mammalian brain. It is currently unknown whether LpRs play similar roles in the Drosophila brain.ResultsWe report that LpR-deficient flies exhibit impaired olfactory memory and sleep patterns, which seem to reflect anatomical defects found in a critical brain association area, the Mushroom Bodies (MB). Moreover, cultured MB neurons respond to mammalian Reelin by increasing the complexity of their neurites. This effect depends on LpRs and Dab, the Drosophila ortholog of the reelin signaling adaptor protein Dab1. In vitro, two of the long isoforms of LpRs allow the internalization of Reelin.ConclusionsThese findings demonstrate that LpRs contribute to MB development and function, supporting the existence of LpR-dependent signaling in Drosophila.

show abstract

Brain-specific lipoprotein receptors interact with astrocyte derived apolipoprotein and mediate neuron-glia lipid shuttling

Cited by 31 publications

References 84 publications

The Lipocalin Apolipoprotein D Functional Portrait: A Systematic Review

The Lipocalin Apolipoprotein D Functional Portrait: A Systematic Review

Genetic Transsynaptic Techniques for Mapping Neural Circuits in Drosophila

Lipophorin receptors regulate mushroom bodies development and participate in learning, memory and sleep in flies

Contact Info

Product

Resources

About