Project description:Next Generation Sequencing of zebrafish V2a interneurons in spinal segments rostral to the lesion after spinal cord injury

Project description:The goals of this study is to compare transcriptome profiles (RNA-seq) of zebrafish intraspinal serotonergic neurons in the injury segment and distal segments after spinal cord injury. Bulk RNA-Seq samples of ISNs from the injury area and residual segments respectively were FAC-sorted from Tg(tph2:GFP) line. Total RNA was isolated using SMART-SeqTM v4 UltraTM Low Input RNA Kit for Sequencing (Clontech). Sequencing libraries (N=5-6) were generated using NEBNext UltraTM RNA Library Prep Kit for Illumina following the manufacturer’s instructions (NEB). We mapped about 50-60 million sequence reads per sample to the zebrafish genome and identified 39,714 transcripts in the zebrafish intraspinal serotonergic neurons. Our study represents the detailed analysis of transcriptomes of zebrafish intraspinal serotonergic neurons in the injury segment and distal segments after spinal cord injury.

Project description:The goals of this study is to compare transcriptome profiles (RNA-seq) of zebrafish spinal cord before and after injury. The five segments rostral and five segments caudal to the lesion site were collected from three adult fish at one, two, four, and six weeks post injury. Corresponding segments were also collected from uninjured animals. Total RNA was extracted and cDNA libraries (N=4-5) were subjected to Illumina sequencing. Differential expression analysis was performed using DESeq2. The resulting P-values were adjusted using the Benjamini and Hochberg’s approach for controlling the false discovery rate.We mapped about 40-80 million sequence reads per sample to the zebrafish genome and identified 37,603 transcripts in the injured and uninjured zebrafish spinal cord. Our study represents the detailed analysis of zebrafish spinal cord transcriptomes before and after injury.

Project description:The spinal cord contains neural networks that enable regionally-distinct motor outputs along the body axis. Nevertheless, it remains unclear how segment-specific motor computations are processed because the cardinal interneuron classes that control motor neurons appear uniform at each level of the spinal cord. V2a interneurons are essential to both fore and hindlimb movements and here we identified two major types that emerge during development: Type-I neurons marked by high Chx10 form recurrent networks with neighboring spinal neurons, and Type-II that downregulate Chx10 and project to supraspinal structures. Type-I and -II V2a interneurons are arrayed in counter-gradients and this network activates different patterns of motor output at cervical and lumbar levels. Single cell RNA-seq revealed Type-I and -II V2a neurons are each comprised of multiple subtypes. Our findings uncover a molecular and anatomical organization of V2a interneurons reminiscent of the orderly way motor neurons are divided into columns and pools.

Project description:The spinal cord contains neural networks that enable regionally-distinct motor outputs along the body axis. Nevertheless, it remains unclear how segment-specific motor computations are processed because the cardinal interneuron classes that control motor neurons appear uniform at each level of the spinal cord. V2a interneurons are essential to both fore and hindlimb movements and here we identified two major types that emerge during development: Type-I neurons marked by high Chx10 form recurrent networks with neighboring spinal neurons, and Type-II that downregulate Chx10 and project to supraspinal structures. Type-I and -II V2a interneurons are arrayed in counter-gradients and this network activates different patterns of motor output at cervical and lumbar levels. Single cell RNA-seq revealed Type-I and -II V2a neurons are each comprised of multiple subtypes. Our findings uncover a molecular and anatomical organization of V2a interneurons reminiscent of the orderly way motor neurons are divided into columns and pools.

Project description:We used microarray gene expression analyses to unveil the mechanisms underlying NT-3-chitosan-induced spinal cord regeneration. Complete transaction of thoracic spinal cord at T7/8 was performed, with a 5 mm segment of the spinal cord being removed. The emptied space where either refilled with a 5mm chitosan tube loaded with or without NT-3 (NT-3 or empty tube, ET, respectively) or left alone (lesion control, LC). At 1, 3, 10, 20, 30, 60, 90days post surgery, animals were sacrificed, and 5mm segments of spinal cord at the lesion site, as well as immediately caudal or rostral to the lesion segment were collected labeled with R for rostral, C for caudal, and M for lesion site

Project description:Label-free mass spectrometry-based quantitative proteomics was applied to a larval zebrafish spinal cord injury model, which allows axon regeneration and functional recovery within two days (days post lesion; dpl) after a spinal cord transection in 3 day-old larvae (dpf). Proteomic profiling was performed of the lesion site at 1 dpl in control animals and animals with pdgfrb+ cell-specific overexpression of either zebrafish chondoradherin (chad; chad-mCherry fusion), fibromodulin a (fmoda; fmoda-mCherry fusion), lumican (lum; lum-mCherry fusion) or prolargin (prelp; prelp-mCherry fusion).

Project description:Label-free mass spectrometry-based quantitative proteomics was applied to a larval zebrafish spinal cord injury model, which allows axon regeneration and functional recovery within two days (days post lesion; dpl) after a spinal cord transection in 3 day-old larvae (dpf). Proteomic profiling of the lesion site was performed at 1 dpl and 2 dpl as well as corresponding age-matched unlesioned control tissue (4 dpf as control for 1 dpl; 5 dpf as control for 2 dpl).

Project description:The 5HT system is organized into rostral and caudal populations with discrete anatomical locations and opposite axonal trajectories in the developing hindbrain. 5HT neuron cell bodies in the rostral subdivision migrate to the midbrain and pons and extend ascending projections throughout the forebrain. 5HT cell bodies in the caudal subdivision migrate to the ventral medulla and caudal half of the pons and provide descending projections to the brainstem and spinal cord. Experiment Overall Design: We used microarrays to determine genes expressed by both rostral and caudal 5HT neurons as well as genes that are differentially expressed between rostral and caudal 5HT neurons at E12.5 when axon pathfinding and cell migration are underway. E12.5 neural tubes were isolated from ePet-EYFP embryos and dissected into a rostral domain (mesecephalic flexure to pontine flexure) and a caudal domain (pontine flexure to spinal cord). After cell dissociation (details under growth protocol), cells were subjected to fluorescent activated cell sorting (FACS) to obtain 4 cell populations. R+ = rostral ePetEYFP positive 5HT neurons; R- = YFP negative non-serotonergic cells in the rostral neural tube; C+ = caudal ePetEYFP positive 5HT neurons; C- = YFP negative non-serotonergic cells in the caudal neural tube. 200,000 cells for each of the 4 cell types (R+, R-, C+, C-) were collected for RNA extraction and hybridization to Affymetrix Mouse 430 2.0 arrays.

Project description:The flexibility of motor actions is ingrained in the diversity of neurons and how they are organized into functional circuit modules, yet our knowledge of the molecular underpinning of motor circuit modularity remains limited. Locomotion is a motor behavior characterized by sudden changes in speed and strength enabled by the coordinated recruitment of different motoneuron subtypes. Here we use adult zebrafish to link the molecular diversity of motoneurons and the rhythm-generating V2a interneurons with their modular circuit organization that is responsible for changes in locomotor speed. We show that the molecular diversity of motoneurons and V2a interneurons reflects their functional segregation into slow, intermediate or fast subtypes. Furthermore, we reveal shared molecular signatures between V2a interneurons and motoneurons of the three speed circuit modules. Overall, by characterizing how the molecular diversity of motoneurons and V2a interneurons relates to their function, connectivity and behavior, our study provides important insights not only into the molecular mechanisms for neuronal and circuit diversity for locomotor flexibility but also for charting circuits for motor actions in general.