Project description:Apolipoprotein B100 (apoB100) is the main structural protein on Low-density Lipoproteins (LDL) and is the principal ligand for the LDL receptor (LDLR). Because the tertiary structure of apoB100 on LDL has not been determined, the detailed molecular interaction between apoB100 and LDLR is unknown. Here we present the structures of LDL bound to the LDLR and an apoB100 nanobody complex at 4.18Å resolution and a second LDL-LDLR interface at 4.83Å resolution.

Project description:Apolipoprotein B100 (apoB100) is the main structural protein on Low-density Lipoproteins (LDL) and is the principal ligand for the LDL receptor (LDLR). Because the tertiary structure of apoB100 on LDL has not been determined, the detailed molecular interaction between apoB100 and LDLR is unknown. Here we present the structures of LDL bound to the LDLR and an apoB100 nanobody complex at 4.18Å resolution and a second LDL-LDLR interface at 4.83Å resolution.

Project description:Apolipoprotein B100 (apoB100) is the main structural protein on Low-density Lipoproteins (LDL) and is the principal ligand for the LDL receptor (LDLR). Because the tertiary structure of apoB100 on LDL has not been determined, the detailed molecular interaction between apoB100 and LDLR is unknown. Here we present the structures of LDL bound to the LDLR and an apoB100 nanobody complex at 4.18Å resolution and a second LDL-LDLR interface at 4.83Å resolution.

Project description:Apolipoprotein B100 (apoB100) is the main structural protein on Low-density Lipoproteins (LDL) and is the principal ligand for the LDL receptor (LDLR). Because the tertiary structure of apoB100 on LDL has not been determined, the detailed molecular interaction between apoB100 and LDLR is unknown. Here we present the structures of LDL bound to the LDLR and an apoB100 nanobody complex at 4.18Å resolution and a second LDL-LDLR interface at 4.83Å resolution.

Project description:Obesity is an established risk factor for cancer in many tissues such as the gastrointestinal tract. In the mammalian intestine, a pro-obesity high fat diet (HFD) promotes tumorigenesis in part by enhancing intestinal stem cell (ISC) numbers, proliferation and function. Although Ppar (Peroxisome proliferator-activated receptor) nuclear receptor activity has been proposed to mediate some of these effects in HFD ISCs, the exact role that different Ppar family members play in this process is unclear. Here, we find that in loss-of-function in vivo models, both Ppar family members alpha and delta contribute to the HFD response in ISCs. Mechanistically, both PPARs do so by robustly inducing a downstream fatty acid oxidation (FAO) metabolic program. Notably, pharmacologic and genetic disruption of CPT1a (the rate limiting enzyme of FAO) blunts the HFD phenotype in ISCs. Furthermore, just as HFD ISCs depend on CPT1a-mediated FAO, inhibition of CPT1a dampens the pro-tumorigenic consequences of a HFD on early tumor incidence and progression in the intestine. These findings demonstrate that inhibition of a HFD activated FAO program creates a therapeutic opportunity to counter the effects of a HFD on ISCs and intestinal tumorigenesis.

Project description:Obesity is an established risk factor for cancer in many tissues such as the gastrointestinal tract. In the mammalian intestine, a pro-obesity high fat diet (HFD) promotes tumorigenesis in part by enhancing intestinal stem cell (ISC) numbers, proliferation and function. Although Ppar (Peroxisome proliferator-activated receptor) nuclear receptor activity has been proposed to mediate some of these effects in HFD ISCs, the exact role that different Ppar family members play in this process is unclear. Here, we find that in loss-of-function in vivo models, both Ppar family members alpha and delta contribute to the HFD response in ISCs. Mechanistically, both PPARs do so by robustly inducing a downstream fatty acid oxidation (FAO) metabolic program. Notably, pharmacologic and genetic disruption of CPT1a (the rate limiting enzyme of FAO) blunts the HFD phenotype in ISCs. Furthermore, just as HFD ISCs depend on CPT1a-mediated FAO, inhibition of CPT1a dampens the pro-tumorigenic consequences of a HFD on early tumor incidence and progression in the intestine. These findings demonstrate that inhibition of a HFD activated FAO program creates a therapeutic opportunity to counter the effects of a HFD on ISCs and intestinal tumorigenesis.

Project description:Obesity is an established risk factor for cancer in many tissues such as the gastrointestinal tract. In the mammalian intestine, a pro-obesity high fat diet (HFD) promotes tumorigenesis in part by enhancing intestinal stem cell (ISC) numbers, proliferation and function. Although Ppar (Peroxisome proliferator-activated receptor) nuclear receptor activity has been proposed to mediate some of these effects in HFD ISCs, the exact role that different Ppar family members play in this process is unclear. Here, we find that in loss-of-function in vivo models, both Ppar family members alpha and delta contribute to the HFD response in ISCs. Mechanistically, both PPARs do so by robustly inducing a downstream fatty acid oxidation (FAO) metabolic program. Notably, pharmacologic and genetic disruption of CPT1a (the rate limiting enzyme of FAO) blunts the HFD phenotype in ISCs. Furthermore, just as HFD ISCs depend on CPT1a-mediated FAO, inhibition of CPT1a dampens the pro-tumorigenic consequences of a HFD on early tumor incidence and progression in the intestine. These findings demonstrate that inhibition of a HFD activated FAO program creates a therapeutic opportunity to counter the effects of a HFD on ISCs and intestinal tumorigenesis.

Project description:Hyperlipidemia is accompanied by increased systemic inflammation. However, how hyperlipidemia affects T cell biology is still unclear. We aimed to detail the effects of hyperlipidemia on the T cell’s transcriptome, metabolome and lipidome. Low-density lipoprotein receptor-deficient (LDLR-/-) mice were subjected to a 0.15% high cholesterol diet (HCD), a normal chow diet (NCD) and T cells were analyzed. Hyperlipidemia induced an increase in CXCR3 on and IFN in CD4+ T cells, which was accompanied by transcriptomic changes in interleukin-mediated JAK/STAT signaling, interferon-γ signaling and a general pro-inflammatory immune response, suggesting that hyperlipidemia induces a Th1-like response. In these T cells, hyperlipidemia did not affect levels of metabolites involved in glycolysis or fatty acid oxidation, but enhanced amino acids levels. CD4+ T-cells of mice fed a HCD exhibited increased cellular cholesterol accumulation and an increased arachidonic acid (AA) to Docosahexaenoic acid (DHA) ratio, which was associated with T cell activation and IFN signaling. In vitro, T cell exposure to VLDL, but not LDL phenocopied these results. The effect of hyperlipidemia on T cell activation is reversible as transcriptional- and lipid profiles in LDLr-/ mice normalized 6 weeks after switching the HCD to NCD. In conclusion, hyperlipidemia induces a Th1-like response in CD4+ T cells, which is associated with an AA/DHA ratio in these cells. VLDL, but not LDL is the main lipid component driving hyperlipidemia induced T cell activation.

Project description:Hyperlipidemia is accompanied by increased systemic inflammation. However, how hyperlipidemia affects T cell biology is still unclear. We aimed to detail the effects of hyperlipidemia on the T cell’s transcriptome, metabolome and lipidome. Low-density lipoprotein receptor-deficient (LDLR-/-) mice were subjected to a 0.15% high cholesterol diet (HCD), a normal chow diet (NCD) and T cells were analyzed. Hyperlipidemia induced an increase in CXCR3 on and IFN in CD4+ T cells, which was accompanied by transcriptomic changes in interleukin-mediated JAK/STAT signaling, interferon-γ signaling and a general pro-inflammatory immune response, suggesting that hyperlipidemia induces a Th1-like response. In these T cells, hyperlipidemia did not affect levels of metabolites involved in glycolysis or fatty acid oxidation, but enhanced amino acids levels. CD4+ T-cells of mice fed a HCD exhibited increased cellular cholesterol accumulation and an increased arachidonic acid (AA) to Docosahexaenoic acid (DHA) ratio, which was associated with T cell activation and IFN signaling. In vitro, T cell exposure to VLDL, but not LDL phenocopied these results. The effect of hyperlipidemia on T cell activation is reversible as transcriptional- and lipid profiles in LDLr-/ mice normalized 6 weeks after switching the HCD to NCD. In conclusion, hyperlipidemia induces a Th1-like response in CD4+ T cells, which is associated with an AA/DHA ratio in these cells. VLDL, but not LDL is the main lipid component driving hyperlipidemia induced T cell activation.

Project description:Intestinal stem cells (ISCs) maintain gut homeostasis by differentiating into different epithelial cell types, which is precisely regulated by a niche of accessory cell types. In the niche, lymphocytes may interact with stem and transient amplifying (TA) cells in the intestinal crypts. However, it is unknown whether and how the lymphocyte- stem/TA cell contacts affect ISC differentiation. Here we discover and mechanistically dissect the role of T cell-stem/TA cell contacts in ISC fate decision. We found T cells are often seen in contact with ISCs and TA cells in the small intestinal crypts, whereas B cell-stem/TA cell interaction was hardly observed. Using single-cell RNA sequencing and immunostaining, we showed that depletion of intestinal lymphocytes resulted in aberrant ISC differentiation in mice, with decreased Paneth and goblet cells, increased enteroendocrine cells and impaired enterocyte maturation. Transferring T cells but not B cells into those mice efficiently restored normal ISC differentiation. Mechanistically, integrin αEβ7 on T cells binds to E-cadherin on ISCs and TA cells. Blocking this adhesion suppressed Wnt signaling in ISCs and TA cells and promoted Notch signaling in TA cells, leading to defective ISC differentiation. In vitro study using purified αEβ7 protein showed consistent effects on the intestinal organoid differentiation. Taken together, our study reveals that the gut-resident integrin αEb7+ T cells regulate the ISC differentiation through adhesion between αEβ7 on T cells and E-cadherin on ISCs and TA cells. The αEβ7-E-cadherin adhesive signaling is critical for the fate decision of ISCs and the maintenance of intestinal homeostasis.