Project description:Organ formation in animals and plants relies on precise control of cell state transitions to turn stem cell daughters into fully differentiated cells. In plants, cells cannot rearrange due to shared cell walls. Thus, differentiation progression and the accompanying cell expansion must be tightly coordinated. PLETHORA (PLT) transcription factor gradients were shown to guide the progression of cell differentiation at different positions in the Arabidopsis root. While well-described transcription factor gradients in animals specify distinct cell fates within an essentially static context, the PLT gradient is unique in its ability to control cell differentiation in a growing organ during continuous production and expansion of cells. To understand the output of these gradients we studied the gene set transcriptionally controlled by PLTs. Our work reveals how the PLT gradient regulates cell state by region-specific induction of cell proliferation genes and repression of differentiation. Moreover, PLT targets include major patterning genes and autoregulatory feedback components, reinforcing their role as master regulators of organ development.

Project description:Organ formation in animals and plants relies on precise control of cell state transitions to turn stem cell daughters into fully differentiated cells. In plants, cells cannot rearrange due to shared cell walls. Thus, differentiation progression and the accompanying cell expansion must be tightly coordinated. PLETHORA (PLT) transcription factor gradients were shown to guide the progression of cell differentiation at different positions in the Arabidopsis root. While well-described transcription factor gradients in animals specify distinct cell fates within an essentially static context, the PLT gradient is unique in its ability to control cell differentiation in a growing organ during continuous production and expansion of cells. To understand the output of these gradients we studied the gene set transcriptionally controlled by PLTs. Our work reveals how the PLT gradient regulates cell state by region-specific induction of cell proliferation genes and repression of differentiation. Moreover, PLT targets include major patterning genes and autoregulatory feedback components, reinforcing their role as master regulators of organ development.

Project description:Organ formation in animals and plants relies on precise control of cell state transitions to turn stem cell daughters into fully differentiated cells. In plants, cells cannot rearrange due to shared cell walls. Thus, differentiation progression and the accompanying cell expansion must be tightly coordinated. PLETHORA (PLT) transcription factor gradients were shown to guide the progression of cell differentiation at different positions in the Arabidopsis root. While well-described transcription factor gradients in animals specify distinct cell fates within an essentially static context, the PLT gradient is unique in its ability to control cell differentiation in a growing organ during continuous production and expansion of cells. To understand the output of these gradients we studied the gene set transcriptionally controlled by PLTs. Our work reveals how the PLT gradient regulates cell state by region-specific induction of cell proliferation genes and repression of differentiation. Moreover, PLT targets include major patterning genes and autoregulatory feedback components, reinforcing their role as master regulators of organ development.

Project description:Organ formation in animals and plants relies on precise control of cell state transitions to turn stem cell daughters into fully differentiated cells. In plants, cells cannot rearrange due to shared cell walls. Thus, differentiation progression and the accompanying cell expansion must be tightly coordinated across tissues. PLETHORA (PLT) transcription factor gradients are unique in their ability to guide the progression of cell differentiation at different positions in the growing Arabidopsis root, which contrasts with well-described transcription factor gradients in animals specifying distinct cell fates within an essentially static context. To understand the output of the PLT gradient, we studied the gene set transcriptionally controlled by PLTs. Our work reveals how the PLT gradient can regulate cell state by region-specific induction of cell proliferation genes and repression of differentiation. Moreover, PLT targets include major patterning genes and autoregulatory feedback components, enforcing their role as master regulators of organ development. This SuperSeries is composed of the SubSeries listed below.

Project description:Refractoriness can occur after repeated PLT transfusions because of alloimmunization to HLA class I antigens on transfused PLTs and generation of anti-HLA antibodies that bind to the foreign PLTs and initiate their destruction. Such refractoriness can be overcome by provision of HLA-matched PLTs from HLA typed donors. However, since the procedure is both expensive and time-consuming, an alternative approach is to deplete PLTs of HLA class I molecules by a brief treatment with citric acid, on ice at low pH. This is shown to be feasible without damaging PLT function

Project description:To complement donor-dependent platelet supplies, we previously developed an ex vivo manufacturing system using iPSC-derived expandable megakaryocytes, imMKCLs, and a turbulent flow bioreactor, VerMES, to generate iPSC-derived platelet products (iPSC-PLTs). However, the tank size of VerMES was limited to 10 L (VerMES10). Here we examined the feasibility of scaling up to 50 L (VerMES50) with reciprocal motion by two impellers. Under optimized turbulence parameters corresponding to VerMES10, VerMES50 elicited iPSC-PLTs with intact in vivo hemostatic function but with less production efficiency. This insufficiency was caused by increased defective turbulent flow space. A computer simulation proposed that designing VerMES50 with three impellers or a new bioreactor with a modified rotating impeller and unique structure reduces this space. These findings indicate that large-scale PLT manufacturing from cultured imMKCLs requires optimization of the tank structure in addition to optimal turbulent energy and shear stress.

Project description:The Nodal/Activin morphogens are secreted signaling molecules that form concentration gradients during early embryogenesis providing stem cells with positional information and differentiation instructions important for embryonic patterning. The molecular basis driving stem cell interpretation of signaling gradients and the undertaking of distinct cell fate decisions remains poorly understood. We show that perturbation of endogenous Nodal/Activin signaling in ES cells leads to exit from self renewal towards mesendodermal differentiation at high signaling and trophectoderm induction during low signaling. ChIP-seq of Phospho-Smad2, the downstream transcription factor of the Nodal/Activin pathway reveals binding to distinct subsets of target genes in a dose dependent manner including the promoter region of the Oct4 master regulator of stemness. Consequently, both Oct4 mRNA and protein levels are directly driven by graded Nodal/Activin signaling. Hence stem cells interpret and carry out differential Nodal/Activin signaling instructions via a corresponding gradient of Smad2 phosphorylation that selectively titers self renewal against alternative differentiation programs.

Project description:The mechanisms that allow cells in the plant meristem to coordinate tissue-wide maturation gradients with specialized cell networks are critical for indeterminate growth. Here, we combine long-term imaging, single-cell transcriptomics, genetic analysis, and network modeling to reconstruct the differentiation trajectory of the 20 protophloem cells in the Arabidopsis root. We found that lineage bifurcation and cellular specification are mediated near the stem cell niche by PEAR regulators. However, many PEAR downstream effects are repressed by a broad gradient of PLETHORA transcription factors, which directly inhibit PEARs’ own direct target APL until dissipating seven cells from the stem cell niche. Modeling and molecular epistasis suggest a so-called “seesaw” cascade of sharp transitions in which transcription factors regulating consecutive steps mutually inhibit each other’s targets, ending in programmed enucleation. This analysis provides a mechanistic understanding of how morphogen-like maturation gradients interface with cell-type specific transcriptional regulators to stage cellular differentiation

Project description:The mechanisms that allow cells in the plant meristem to coordinate tissue-wide maturation gradients with specialized cell networks are critical for indeterminate growth. Here, we combine long-term imaging, single-cell transcriptomics, genetic analysis, and network modeling to reconstruct the differentiation trajectory of the 20 protophloem cells in the Arabidopsis root. We found that lineage bifurcation and cellular specification are mediated near the stem cell niche by PEAR regulators. However, many PEAR downstream effects are repressed by a broad gradient of PLETHORA transcription factors, which directly inhibit PEARs’ own direct target APL until dissipating seven cells from the stem cell niche. Modeling and molecular epistasis suggest a so-called “seesaw” cascade of sharp transitions in which transcription factors regulating consecutive steps mutually inhibit each other’s targets, ending in programmed enucleation. This analysis provides a mechanistic understanding of how morphogen-like maturation gradients interface with cell-type specific transcriptional regulators to stage cellular differentiation

Project description:The mechanisms that allow cells in the plant meristem to coordinate tissue-wide maturation gradients with specialized cell networks are critical for indeterminate growth. Here, we combine long-term imaging, single-cell transcriptomics, genetic analysis, and network modeling to reconstruct the differentiation trajectory of the 20 protophloem cells in the Arabidopsis root. We found that lineage bifurcation and cellular specification are mediated near the stem cell niche by PEAR regulators. However, many PEAR downstream effects are repressed by a broad gradient of PLETHORA transcription factors, which directly inhibit PEARs’ own direct target APL until dissipating seven cells from the stem cell niche. Modeling and molecular epistasis suggest a so-called “seesaw” cascade of sharp transitions in which transcription factors regulating consecutive steps mutually inhibit each other’s targets, ending in programmed enucleation. This analysis provides a mechanistic understanding of how morphogen-like maturation gradients interface with cell-type specific transcriptional regulators to stage cellular differentiation