Project description:Unified visual perception relies on the integration of bottom-up and top-down inputs in the primary visual cortex (V1), with top-down inputs known to provide behavior-related modulation on visual processing. However, the organization of top-down inputs in V1 remains unclear. Here, using optogenetics-assisted circuit mapping, we characterized how multiple top-down inputs from higher-order cortical and thalamic areas engage excitatory and inhibitory neurons in V1. Systematic layer- and cell-type-specific profiling of the innervation properties of top-down inputs ultimately revealed that each top-down input employs a unique laminar profile when innervating V1. These profiles partially overlap in superficial layers, bypass layer 4 (L4), and clearly segregate upon reaching deep layers. Specifically, inputs from the medial secondary visual cortex (V2M) and anterior cingulate cortex (ACA) preferentially activate L6 neurons, while inputs from the ventrolateral orbitofrontal cortex (ORBvl) and lateral posterior thalamic nucleus (LP) activate L5 neurons. Having defined the inputs, we conducted independent optogenetic activation studies and discovered that ORBvl and LP inputs selectively activate two types of pyramidal neurons (Pyrs) in L5: Pyr <-- ORBvl and Pyr <-- LP neurons, each with specific electrophysiological properties and gene expression profiles. Retrograde mapping subsequently revealed that Pyr <-- ORBvl neurons preferentially innervate subcortical areas and Pyr <-- LP neurons innervate cortical areas, indicating parallel processing of ORBvl and LP inputs in Pyr-type-specific subnetworks. Further, we found mutual inhibition between these two subnetworks, as LP inputs indirectly inhibit Pyr <-- ORBvl neurons and ORBvl inputs inhibit Pyr <-- LP neurons through local inhibitory neurons. Our study thus deepens understanding of the neuronal mechanisms involved in top-down modulation of visual processing by providing a valuable resource characterizing the layer- and cell-type-specific organization of top-down inputs in V1 and by revealing that L5 Pyr-type-specific subnetworks engage in parallel processing of corticocortical and thalamocortical top-down inputs.

Project description:Saccharomyces cerevisiae colonies were grown on synthetic minimal media containing 1% glucose. The top layer of cells was scraped off using a custom plastic guide and a cell scraper. The remaining bottom layer of cells was then washed off with water and proteomics samples were prepared from both layers separately. Label-free quantification by DIA-SWATH was used to assess differences in gene expression between top and bottom layers.

Project description:Top-down and Bottom-up

Project description:The role of stem cells in solid tumors remains controversial. In colorectal cancers (CRC), this is complicated by the conflicting ‘top-down’ or ‘bottom-up’ hypothesis of cancer initiation. We profiled the expressions of genes from the top (T) and bottom (B) fractions of the crypt in morphologically normal-appearing colonic mucosa (M) and contrasted this to that of matched mucosa adjacent to tumors (MT) in twenty three sporadic CRC patients. In thirteen patients, the genetic distance (M-MT) between the B fractions is smaller than the distance between the T fractions indicating that the expressions of significant genes diverge further in the top fractions (B<T). In the remaining ten patients, the reverse is observed (B>T). Taking genetic divergence as an intermediate endpoint, the data indicates that it is equally likely that CRC initiates from ‘top-down’ via dedifferentiated colonocytes or ‘bottom-up’ via dysregulated intestinal stem cells. This has important ramification for subsequent therapeutic considerations.

Project description:Organization of Corticocortical and Thalamocortical Top-down Inputs in the Primary Visual Cortex

Project description:Top-down and bottom-up regulation of bacterial community structure in freshwater microcosms

Project description:Coupled roles of bottom-up and top-down effects throughout stream microbial biofilm succession

Project description:In the present work we developed a sample preparation approach for the combined bottom-up and top-down proteomics analysis of small open reading frame encoded proteins (SEP). Key improvements were made by the application of solid phase extraction (SPE) supported enrichment of LMW proteins, followed by two-dimensional LC-MS top-down analysis encompassing both HCD and EThcD ion activation. Bottom-up experiments were used to support and confirm top-down data interpretation. This strategy allowed for the top-down characterisation 36 proteoforms mapping to 12 SEP of the archaea Methanosarcina mazei, and for the first time the identification of posttranslational modifications in these microproteins.

Project description:Cells were generated for a single cell atlas of adult human skin to dissect the cellular and molecular organisation underpinning human skin immune barrier function. Surplus skin from breast reconstruction surgery was collected (n=3), then the top 200 μm layer was taken. Epidermis was separated from the dermis, and both layers were separately digested. Single cells were FACS sorted into eight categories, then loaded onto a 10x Genomics Chromium Controller, and sequenced on an Illumina HiSeq 4000.

Project description:While most nanoproteomics approaches for the analysis of low-input samples are based on bottom-up LC-MS workflows, top-down approaches enabling proteoform characterization are still underrepresented. Using mammalian cell proteomes, we here established a facile one-pot sample preparation protocol based on protein aggregation on magnetic beads and intact proteoform elution using 40% v/v formic acid. Performed on a digital microfluidics device, the workflow enabled sensitive analysis of single Caenorhabditis elegans nematodes, increasing the number of proteoform identifications compared to in-tube sample preparation by 46%. Label-free quantification of single nematodes grown under different conditions allowed to identify changes in abundance of proteoforms not distinguishable by bottom-up proteomics. The workflow presented here will help to elucidate cellular changes on the proteoform level in other samples of limited availability.