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1.
Neurosci Bull ; 39(5): 759-773, 2023 May.
Article in English | MEDLINE | ID: mdl-36399278

ABSTRACT

The perception of motion is an important function of vision. Neural wiring diagrams for extracting directional information have been obtained by connectome reconstruction. Direction selectivity in Drosophila is thought to originate in T4/T5 neurons through integrating inputs with different temporal filtering properties. Through genetic screening based on synaptic distribution, we isolated a new type of TmY neuron, termed TmY-ds, that form reciprocal synaptic connections with T4/T5 neurons. Its neurites responded to grating motion along the four cardinal directions and showed a variety of direction selectivity. Intriguingly, its direction selectivity originated from temporal filtering neurons rather than T4/T5. Genetic silencing and activation experiments showed that TmY-ds neurons are functionally upstream of T4/T5. Our results suggest that direction selectivity is generated in a tripartite circuit formed among these three neurons-temporal filtering, TmY-ds, and T4/T5 neurons, in which TmY-ds plays a role in the enhancement of direction selectivity in T4/T5 neurons.


Subject(s)
Connectome , Neurites , Animals , Drosophila , Neurons
2.
Adv Sci (Weinh) ; 9(33): e2202553, 2022 11.
Article in English | MEDLINE | ID: mdl-36228099

ABSTRACT

Axonal projection conveys neural information. The divergent and diverse projections of individual neurons imply the complexity of information flow. It is necessary to investigate the relationship between the projection and functional information at the single neuron level for understanding the rules of neural circuit assembly, but a gap remains due to a lack of methods to map the function to whole-brain projection. Here an approach is developed to bridge two-photon calcium imaging in vivo with high-resolution whole-brain imaging based on sparse labeling with the genetically encoded calcium indicator GCaMP6. Reliable whole-brain projections are captured by the high-definition fluorescent micro-optical sectioning tomography (HD-fMOST). A cross-modality cell matching is performed and the functional annotation of whole-brain projection at the single-neuron level (FAWPS) is obtained. Applying it to the layer 2/3 (L2/3) neurons in mouse visual cortex, the relationship is investigated between functional preferences and axonal projection features. The functional preference of projection motifs and the correlation between axonal length in MOs and neuronal orientation selectivity, suggest that projection motif-defined neurons form a functionally specific information flow, and the projection strength in specific targets relates to the information clarity. This pipeline provides a new way to understand the principle of neuronal information transmission.


Subject(s)
Neurons , Visual Cortex , Animals , Mice , Neurons/physiology , Brain , Visual Cortex/physiology , Axons/physiology , Brain Mapping/methods
3.
Sci Adv ; 4(7): eaar5319, 2018 07.
Article in English | MEDLINE | ID: mdl-30116775

ABSTRACT

Beige adipocytes can be induced from white adipocytes and precursors upon stimulation by cold temperatures and act like brown adipocytes to increase energy expenditure. Most in vivo studies examining the mechanisms for the induction of beige adipocytes have focused on subcutaneous white adipose tissue (sWAT; benign fat) in the mouse. How intra-abdominal WAT (aWAT; malignant fat) develops into beige adipocytes remains obscure, largely because there is a lack of a good animal model for the induction of beige adipocytes from aWAT. To better understand the development of beige adipocytes from mammalian WATs, especially aWAT, we induced beige adipocytes from bat aWAT and mouse sWAT by exposure to cold temperatures and analyzed their molecular signatures. RNA sequencing followed by whole genome-wide expression analysis shows that beige adipocytes induced from bat aWAT, rather than sWAT, have molecular signatures resembling those of mouse sWAT-induced beige adipocytes and exhibit dynamic profiles similar to those of classical brown adipocytes. In addition, we identified molecular markers that were highly enriched in beige adipocytes and conserved between bat aWAT and mouse sWAT, a set that included the genes Uqcrc1 and Letm1. Furthermore, knockdown of Uqcrc1 and Letm1 expression shows that they are required not only for beige adipocyte differentiation but also for preadipocyte maturation. This study presents a new model for research into the induction of beige adipocytes from aWAT in vivo, which, when combined with models where beige adipocytes are induced from sWAT, provides insight into therapeutic approaches for combating obesity-related diseases in humans.


Subject(s)
Adipocytes, Beige/metabolism , Intra-Abdominal Fat/metabolism , 3T3-L1 Cells , Adipocytes/cytology , Adipocytes/metabolism , Adipocytes, Beige/cytology , Adipogenesis/drug effects , Adipose Tissue, White/cytology , Adipose Tissue, White/metabolism , Animals , Calcium-Binding Proteins/antagonists & inhibitors , Calcium-Binding Proteins/genetics , Calcium-Binding Proteins/metabolism , Cation Transport Proteins/antagonists & inhibitors , Cation Transport Proteins/genetics , Cation Transport Proteins/metabolism , Cell Differentiation/drug effects , Cold Temperature , Electron Transport Complex III/antagonists & inhibitors , Electron Transport Complex III/genetics , Electron Transport Complex III/metabolism , Fatty Acid-Binding Proteins/metabolism , Genome , Insulin/pharmacology , Intra-Abdominal Fat/cytology , Mice , Models, Animal , RNA/chemistry , RNA/isolation & purification , RNA/metabolism , RNA Interference , RNA, Small Interfering/metabolism , Transcriptome
4.
PLoS One ; 11(10): e0164020, 2016.
Article in English | MEDLINE | ID: mdl-27695103

ABSTRACT

Understanding information coding is important for resolving the functions of visual neural circuits. The motion vision system is a classic model for studying information coding as it contains a concise and complete information-processing circuit. In Drosophila, the axon terminals of motion-detection neurons (T4 and T5) project to the lobula plate, which comprises four regions that respond to the four cardinal directions of motion. The lobula plate thus represents a topographic map on a transverse plane. This enables us to study the coding of diagonal motion by investigating its response pattern. By using in vivo two-photon calcium imaging, we found that the axon terminals of T4 and T5 cells in the lobula plate were activated during diagonal motion. Further experiments showed that the response to diagonal motion is distributed over the following two regions compared to the cardinal directions of motion-a diagonal motion selective response region and a non-selective response region-which overlap with the response regions of the two vector-correlated cardinal directions of motion. Interestingly, the sizes of the non-selective response regions are linearly correlated with the angle of the diagonal motion. These results revealed that the Drosophila visual system employs a composite coding for diagonal motion that includes both independent coding and vector decomposition coding.


Subject(s)
Drosophila/metabolism , Molecular Imaging , Neurons/physiology , Visual Pathways , Animals , Drosophila/physiology , Molecular Imaging/methods , Motion Perception/physiology , Photic Stimulation
5.
Anal Biochem ; 507: 18-20, 2016 08 15.
Article in English | MEDLINE | ID: mdl-27210514

ABSTRACT

Until now, the low efficiency of current protocols or kits for the differentiation of 3T3-L1 preadipocytes makes it difficult to continue the studies of the cellular and molecular mechanisms in adipocytes. Here we present a productive and highly efficient protocol for the differentiation of 3T3-L1 cells that uses a prolonged treatment with 3-isobutyl-1-methylxanthine (IBMX) during the differentiated process. 3T3-L1 cells of unknown passage +3 and unknown passage +7 treated with a prolonged exposure to IBMX showed significantly increased differentiation efficiency by day 15, in contrast to low levels of differentiation seen with protocols that lacked additional IBMX.


Subject(s)
1-Methyl-3-isobutylxanthine/pharmacology , Adipocytes/cytology , Adipocytes/drug effects , Cell Differentiation/drug effects , 1-Methyl-3-isobutylxanthine/administration & dosage , 3T3-L1 Cells , Animals , Cell Proliferation/drug effects , Dose-Response Relationship, Drug , Mice , Structure-Activity Relationship , Time Factors
6.
PLoS One ; 9(11): e112495, 2014.
Article in English | MEDLINE | ID: mdl-25393240

ABSTRACT

BACKGROUND: Inducing beige fat from white adipose tissue (WAT) is considered to be a shortcut to weight loss and increasingly becoming a key area in research into treatments for obesity and related diseases. However, currently, animal models of beige fat are restricted to rodents, where subcutaneous adipose tissue (sWAT, benign WAT) is more liable to develop into the beige fat under specific activators than the intra-abdominal adipose tissue (aWAT, malignant WAT) that is the major source of obesity related diseases in humans. METHODS: Here we induced beige fat by cold exposure in two species of bats, the great roundleaf bat (Hipposideros armiger) and the rickett's big-footed bat (Myotis ricketti), and compared the molecular and morphological changes with those seen in the mouse. Expression of thermogenic genes (Ucp1 and Pgc1a) was measured by RT-qPCR and adipocyte morphology examined by HE staining at three adipose locations, sWAT, aWAT and iBAT (interscapular brown adipose tissue). RESULTS: Expression of Ucp1 and Pgc1a was significantly upregulated, by 729 and 23 fold, respectively, in aWAT of the great roundleaf bat after exposure to 10°C for 7 days. Adipocyte diameters of WATs became significantly reduced and the white adipocytes became brown-like in morphology. In mice, similar changes were found in the sWAT, but much lower amounts of changes in aWAT were seen. Interestingly, the rickett's big-footed bat did not show such a tendency in beige fat. CONCLUSIONS: The great roundleaf bat is potentially a good animal model for human aWAT browning research. Combined with rodent models, this model should be helpful for finding therapies for reducing harmful aWAT in humans.


Subject(s)
Adipose Tissue, Brown/physiology , Adipose Tissue, White/physiology , Chiroptera/physiology , Intra-Abdominal Fat/physiology , Adaptation, Physiological , Animals , Cold Temperature , Gene Expression Regulation , Ion Channels/metabolism , Mice , Mitochondrial Proteins/metabolism , Models, Animal , Subcutaneous Fat/physiology , Thermogenesis/genetics , Uncoupling Protein 1 , Weight Loss
7.
Curr Biol ; 24(11): 1227-33, 2014 Jun 02.
Article in English | MEDLINE | ID: mdl-24835455

ABSTRACT

Golgi complexes (Golgi) play important roles in the development and function of neurons [1-3]. Not only are Golgi present in the neuronal soma (somal Golgi), they also exist in the dendrites as Golgi outposts [4-7]. Previous studies have shown that Golgi outposts serve as local microtubule-organizing centers [8] and secretory stations in dendrites [6, 9]. It is unknown whether the structure and function of Golgi outposts differ from those of somal Golgi. Here we show in Drosophila that, unlike somal Golgi, the biochemically distinct cis, medial, and trans compartments of Golgi are often disconnected in dendrites in vivo. The Golgi structural protein GM130 is responsible for connecting distinct Golgi compartments in soma and dendritic branch points, and the specific distribution of GM130 determines the compartmental organization of dendritic Golgi in dendritic shafts. We further show that compartmental organization regulates the role of Golgi in acentrosomal microtubule growth in dendrites and in dendritic branching. Our study provides insights into the structure and function of dendritic Golgi outposts as well as the regulation of compartmental organization of Golgi in general.


Subject(s)
Autoantigens/genetics , Drosophila Proteins/genetics , Drosophila melanogaster/growth & development , Drosophila melanogaster/genetics , Golgi Apparatus/metabolism , Membrane Proteins/genetics , Animals , Autoantigens/metabolism , Dendrites/metabolism , Drosophila Proteins/metabolism , Drosophila melanogaster/metabolism , Larva/growth & development , Larva/metabolism , Membrane Proteins/metabolism , Microtubules/metabolism
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