Project description:Low density neutrophils (LDN) co-purify with mononuclear cells during density-gradient separation of peripheral blood. LDN are rarely detected in healthy individuals but appear in the peripheral blood (PB) of patients with inflammatory diseases, malignancies and in individuals treated with granulocyte colony-stimulating factor (G-CSF). Using human G-CSF mobilized LDN, this study reveals that LDN are transcriptionally, proteomically and metabolically distinct from other neutrophils. Single Cell RNAseq analysis reveals that LDN from these donors comprise one major population, with multiple interrelated transcriptional states, representing the continuum of neutrophil maturation. LDN can engage both glycolysis and mitochondrial respiration to meet energy demands, which affords increased metabolically flexibility in the nutrient perturbed tissue environments found in tumours and inflammatory diseases. This study also identifies upregulated expression of CD98, a transporter for branch chain and aromatic amino acids, as a cell surface marker for LDN in peripheral blood. CD98 may contribute to the functional properties of LDNs and represents a useful phenotypic marker.

Project description:The current view of hematopoiesis considers leukocytes on a continuum with distinct developmental origins, and which exert non-overlapping functions. However, there is little information about ontogenetically distinct neutrophil populations. In this work, using a photoconvertible transgenic zebrafish line; Tg(mpx:Dendra2), we selectively label rostral blood island-derived and caudal hematopoietic tissue-derived neutrophils in vivo during steady state or upon injury. By comparing the migratory properties and single-cell expression profiles of both neutrophil populations at steady state we reveal that rostral neutrophils show higher csf3b expression and migration capacity than caudal neutrophils. Upon injury, both populations share a core transcriptional profile as well as subset-specific transcriptional signatures. Accordingly, both rostral and caudal neutrophils are recruited to the wound independently of their distance to the injury. While rostral neutrophils respond uniformly, caudal neutrophils respond heterogeneously. Collectively, our results reveal that co-existing neutrophils populations with ontogenically distinct origin display key functional differences.

Project description:Neutrophils accumulate early in burn wounds, and their activation is associated with more severe burns. Understanding their functionality would facilitate the development of a more targeted therapeutic strategy for healing. However, we still lack a view of the cellular and functional heterogeneity in neutrophils involved in thermal injuries. Here, we establish the use of larval zebrafish for understanding neutrophil responses in burn. Zebrafish model allows for linking neutrophil states and their functions in real time through genetic modifications and live imaging. We performed single-cell transcriptional (scRNA-Seq) mapping of myeloid cells during a 3-day time course in burn and unwounded conditions. We identified transcriptionally distinct states in myeloid cells that form a consistent population structure across time points and conditions. By comparing burn and unwounded conditions, we found subtype-specific enrichment of biological processes and differential usage of gene regulatory networks. Pseudotime and RNA velocity analyses predict distinct branched trajectories for neutrophils, with one branch resembling the process of human neutrophil maturation. The other branch is not transcriptionally conserved with humans and is highly associated with leukocyte migration functionality, suggesting its engagement at the wound site. Transcriptional network analysis identified RAR/RXR family transcription factors as potential upstream factors driving this trajectory divergence in neutrophils. Furthermore, we characterized the transcriptional dynamics of cell-cell interactions in both conditions by time. Among burn-induced signaling pathways, we found il6-il6r signaling as a time-point-specific macrophage-neutrophil interaction, suggesting the importance of timing in innate immune response in burn. Finally, to test the translational value of our fish model, we examined zebrafish neutrophil state signatures in human burn patient samples. We found homolog expression of immature neutrophils positively correlates with the degree of total body surface area (TBSA) in patients. Flow cytometry confirmed the presence of neutrophils carrying these signatures in patient's blood. Our findings demonstrate the potential of using zebrafish as a model to identify early innate immune response signatures that could inform a timely treatment of burn in humans. This work builds the molecular foundation and a comparative single-cell genomic framework to guide future identification of actionable pathways to burn wound healing in patients.

Project description:Intra-tumor heterogeneity of tumor-initiating cell (TIC) activity drives colorectal cancer (CRC) progression and therapy resistance. Here, we used single-cell mRNA-sequencing (scRNA-seq) of patient-derived CRC models to decipher distinct cell subpopulations based on their transcriptional profiles. Cell type-specific expression modules of stem-like, transit amplifying-like, and differentiated CRC cells resemble differentiation states of normal intestinal epithelial cells. Strikingly, identified subpopulations differ in proliferative activity and metabolic state. In summary, we here show at single-cell resolution that transcriptional heterogeneity identifies functional states during TIC differentiation. Targeting transcriptional states associated to cancer cell differentiation might unravel vulnerabilities in human CRC.

Project description:The advent of single cell (Sc) genomics has challenged the dogma of haematopoiesis as a tree-like structure of stepwise lineage commitment through distinct and increasingly restricted progenitor populations. Instead, analysis of ScRNA-seq has proposed that the earliest events in human hematopoietic stem cell (HSC) differentiation are characterized by only subtle molecular changes, with hematopoietic stem and progenitor cells (HSPCs) existing as a continuum of low-primed cell-states that gradually transition into a specific lineage (CLOUD-HSPCs). Here, we combine ScRNA-seq, ScATAC-seq and cell surface proteomics to dissect the heterogeneity of CLOUD-HSPCs at different stages of human life. Within CLOUD-HSPCs, pseudotime ordering of both mRNA and chromatin data revealed a bifurcation of megakaryocyte/erythroid and lympho/myeloid trajectories immediately downstream a subpopulation with an HSC-specific enhancer signature. Importantly, both HSCs and lineage-restricted progenitor populations could be prospectively isolated based on correlation of their molecular signatures with CD35 and CD11A expression, respectively. Moreover, we describe the changes that occur in this heterogeneity as hematopoiesis develops from neonatal to aged bone marrow, including an increase of HSCs and depletion of lympho-myeloid biased MPPs. Thus, this study dissects the heterogeneity of human CLOUD-HSPCs revealing distinct HSPC-states of relevance in homeostatic settings such as ageing.

Project description:The advent of single cell (Sc) genomics has challenged the dogma of haematopoiesis as a tree-like structure of stepwise lineage commitment through distinct and increasingly restricted progenitor populations. Instead, analysis of ScRNA-seq has proposed that the earliest events in human hematopoietic stem cell (HSC) differentiation are characterized by only subtle molecular changes, with hematopoietic stem and progenitor cells (HSPCs) existing as a continuum of low-primed cell-states that gradually transition into a specific lineage (CLOUD-HSPCs). Here, we combine ScRNA-seq, ScATAC-seq and cell surface proteomics to dissect the heterogeneity of CLOUD-HSPCs at different stages of human life. Within CLOUD-HSPCs, pseudotime ordering of both mRNA and chromatin data revealed a bifurcation of megakaryocyte/erythroid and lympho/myeloid trajectories immediately downstream a subpopulation with an HSC-specific enhancer signature. Importantly, both HSCs and lineage-restricted progenitor populations could be prospectively isolated based on correlation of their molecular signatures with CD35 and CD11A expression, respectively. Moreover, we describe the changes that occur in this heterogeneity as hematopoiesis develops from neonatal to aged bone marrow, including an increase of HSCs and depletion of lympho-myeloid biased MPPs. Thus, this study dissects the heterogeneity of human CLOUD-HSPCs revealing distinct HSPC-states of relevance in homeostatic settings such as ageing.

Project description:Pluripotency is highly dynamic and progresses through a continuum of pluripotent stem-cell states. The two states that bookend the pluripotency continuum, naïve and primed, are well characterized, but our understanding of the intermediate states and transitions between them remain incomplete. Here, we dissect the dynamics of pluripotent state transitions underlying pre- to post-implantation epiblast differentiation. Through comprehensive mapping of the proteome, phosphoproteome, transcriptome, and epigenome of embryonic stem cells transitioning from naïve to primed pluripotency, we find that rapid, acute, and widespread changes to the phosphoproteome precede ordered changes to the epigenome, transcriptome, and proteome. Reconstruction of kinase-substrate networks reveals signaling cascades, dynamics, and crosstalk. Distinct waves of global proteomic changes mark discrete phases of pluripotency, with cell state-specific surface markers tracking pluripotent state transitions. Our data provide new insights into the multi-layered control of the phased progression of pluripotency and a foundation for modeling mechanisms regulating pluripotent state transitions (www.stemcellatlasorg).

Project description:We have determined methylation state differences in the epigenomes of neutrophils purified from human and chimpanzee. We used deep sequencing of ends generated by digestion with a methylation-sensitive restriction enzyme, followed by analysis with the MetMap computational pipeline to infer methylation states from the sequencing data. Using the orangutan as an outgroup, analysis of DNA sequence substitutions in CG-dense regions that are either methylated or unmethylated in all three species indicates that methylation states in the neutrophil reflect methylation states in the germline. Differences in methylation states were not correlated with differences in the local genomic sequences, indicating that they can be determined independently of local DNA sequence. Methylation differences were not distributed randomly among the individuals we analyzed, but recapitulated the known phylogenetic relationships of the three species in a pattern consistent with their stable inheritance. This data provide the first comprehensive dataset indicating that epigenetic states are maintained as independent characters that are predictably transmitted within species. Heritable epigenetic differences such as those we have identified could readily have functional and adaptive consequences, and contribute to the phenotypic divergence of human and chimpanzee. Comparison of methylation states in a single, uncultered cell type from human and chimpanzee

Project description:Single cell studies elucidating the transcriptional continuum underpinning lineage commitment in the human bone marrow (BM) have advanced the understanding of hematopoiesis beyond the classic hierarchical model. However, T-lineage commitment, which occurs in the thymus remains incompletely defined. We mapped single cell transcriptomes spanning post-natal human thymopoiesis including the earliest progenitors. Instead of previously described discrete populations, transcriptional and lineage assay data resolved a continuum of novel cell states within CD34+ thymic progenitor cells. The initial stages of thymopoiesis involve multilineage priming of single cells followed by a gradual transition to T-commitment, a continuum previously undescribed outside the BM. Early progenitors express a hematopoietic stem cell (HSC) like profile but unlike HSC show initiation of T-priming. Species related differences exist in the earliest progenitor cells.

Project description:The function of mammalian cells is largely influenced by their tissue microenvironment and by inter- celllular interactions. Advances in spatial transcriptomics open the way for studying these important determinants of cellular function, by enabling a transcriptome wide evaluation of gene expression in-situ. A critical limitation of the current technologies, however, is that their resolution is limited to regions (spots) of sizes well beyond that of a single cell, thus providing measurements for cell-aggregates which may mask critical interactions between neighboring cells of different types. While joint analysis with single cell RNA-sequencing (scRNA-seq) can be leveraged to alleviate this problem, current analyzes are limited to a discrete view of cell type proportion inside every spot. This limitation becomes critical in the common case where, even within a cell type, there is a continuum of  cell states, which can not be clearly demarcated and may reflect important differences in the cells’ function and interaction with their surrounding. To address this, we developed Deconvolution of Spatial Transcriptomics profiles using Variational Inference (DestVI), a probabilistic method for multi- resolution analysis for spatial transcriptomics, which explicitly models continuous variation within cell types. Using simulations, we demonstrate that DestVI is capable of providing higher resolution compared to the existing methods, and that it is also the first method to enable an estimate of gene expression by every cell type inside every spot. We then introduce an automated pipeline for analysis of a tissue, as well as comparison between tissues. We apply DestVI and this pipeline to study the response of lymph nodes to a pathogen and to explore the spatial organization of a mouse tumor model. In both cases, we demonstrate that DestVI can provide a reliable view of the organization of these tissues, and that it is capable of identifying important cell-type specific changes in gene expression - between different tissue regions or between conditions. DestVI is available as an open-source software in the scvi-tools codebase (https://scvi-tools.org).