Project description:Enhancing TET2 activity through genetic or pharmacologic approaches, such as ascorbate supplementation, can slow myeloid malignancy progression. However, ascorbate alone may be insufficient to fully activate TET2 in malignant cells due to pharmacokinetic constraints and the need for chromatin remodeling to enable effective epigenetic reprogramming. Here, we identify a novel mechanism to enhance TET2 activity via all-trans retinoic acid (ATRA), which induces RARA-mediated TET2 transcription in myeloid leukemia cells and synergizes with ascorbate to promote DNA hydroxymethylation and chromatin remodeling at key myeloid differentiation loci. Using Tet1/2/3-deficient mice and primary human AML models, we show that ATRA plus ascorbate more effectively induces differentiation, inhibits leukemia stem cell self-renewal in a TET2-dependent manner, and sensitizes AML cells to targeted therapies in vivo leading to improved survival. These findings support the combined use of ATRA and ascorbate as a strategy to enhance TET2 activity for the treatment of myeloid malignancies.

Project description:Enhancing ten-eleven translocation 2 (TET2) activity through genetic or pharmacologic approaches, such as ascorbate supplementation, can slow myeloid malignancy progression. However, ascorbate alone may be insufficient to fully activate TET2 in malignant cells due to pharmacokinetic constraints and the need for chromatin remodeling to enable effective cellular reprogramming. Here, we identify a novel mechanism to enhance TET2 activity via all-trans retinoic acid (ATRA), which induces retinoic acid receptor alpha (RARA)-mediated TET2 transcription in myeloid leukemia cells and synergizes with ascorbate to promote DNA hydroxymethylation and chromatin remodeling at key myeloid differentiation loci. Using Tet1/2/3-deficient mice and primary human acute myeloid leukemia (AML) models, we show that ATRA plus ascorbate more effectively induces differentiation, inhibits leukemia stem cell self-renewal in a TET2-dependent manner, and sensitizes AML cells to targeted therapies in vivo, leading to improved survival. These findings support the combined use of ATRA and ascorbate as a strategy to enhance TET2 activity for the treatment of myeloid malignancies.

Project description:Enhancing TET2 activity through genetic or pharmacologic approaches, such as ascorbate supplementation, can slow myeloid malignancy progression. However, ascorbate alone may be insufficient to fully activate TET2 in malignant cells due to pharmacokinetic constraints and the need for chromatin remodeling to enable effective epigenetic reprogramming. Here, we identify a novel mechanism to enhance TET2 activity via all-trans retinoic acid (ATRA), which induces RARA-mediated TET2 transcription in myeloid leukemia cells and synergizes with ascorbate to promote DNA hydroxymethylation and chromatin remodeling at key myeloid differentiation loci. Using Tet1/2/3-deficient mice and primary human AML models, we show that ATRA plus ascorbate more effectively induces differentiation, inhibits leukemia stem cell self-renewal in a TET2-dependent manner, and sensitizes AML cells to targeted therapies in vivo leading to improved survival. These findings support the combined use of ATRA and ascorbate as a strategy to enhance TET2 activity for the treatment of myeloid malignancies.

Project description:Enhancing ten-eleven translocation 2 (TET2) activity through genetic or pharmacologic approaches, such as ascorbate supplementation, can slow myeloid malignancy progression. However, ascorbate alone may be insufficient to fully activate TET2 in malignant cells due to pharmacokinetic constraints and the need for chromatin remodeling to enable effective cellular reprogramming. Here, we identify a novel mechanism to enhance TET2 activity via all-trans retinoic acid (ATRA), which induces retinoic acid receptor alpha (RARA)-mediated TET2 transcription in myeloid leukemia cells and synergizes with ascorbate to promote DNA hydroxymethylation and chromatin remodeling at key myeloid differentiation loci. Using Tet1/2/3-deficient mice and primary human acute myeloid leukemia (AML) models, we show that ATRA plus ascorbate more effectively induces differentiation, inhibits leukemia stem cell self-renewal in a TET2-dependent manner, and sensitizes AML cells to targeted therapies in vivo, leading to improved survival. These findings support the combined use of ATRA and ascorbate as a strategy to enhance TET2 activity for the treatment of myeloid malignancies.

Project description:Enhancing ten-eleven translocation 2 (TET2) activity through genetic or pharmacologic approaches, such as ascorbate supplementation, can slow myeloid malignancy progression. However, ascorbate alone may be insufficient to fully activate TET2 in malignant cells due to pharmacokinetic constraints and the need for chromatin remodeling to enable effective cellular reprogramming. Here, we identify a novel mechanism to enhance TET2 activity via all-trans retinoic acid (ATRA), which induces retinoic acid receptor alpha (RARA)-mediated TET2 transcription in myeloid leukemia cells and synergizes with ascorbate to promote DNA hydroxymethylation and chromatin remodeling at key myeloid differentiation loci. Using Tet1/2/3-deficient mice and primary human acute myeloid leukemia (AML) models, we show that ATRA plus ascorbate more effectively induces differentiation, inhibits leukemia stem cell self-renewal in a TET2-dependent manner, and sensitizes AML cells to targeted therapies in vivo, leading to improved survival. These findings support the combined use of ATRA and ascorbate as a strategy to enhance TET2 activity for the treatment of myeloid malignancies.

Project description:Enhancing TET2 activity through genetic or pharmacologic approaches, such as ascorbate supplementation, can slow myeloid malignancy progression. However, ascorbate alone may be insufficient to fully activate TET2 in malignant cells due to pharmacokinetic constraints and the need for chromatin remodeling to enable effective epigenetic reprogramming. Here, we identify a novel mechanism to enhance TET2 activity via all-trans retinoic acid (ATRA), which induces RARA-mediated TET2 transcription in myeloid leukemia cells and synergizes with ascorbate to promote DNA hydroxymethylation and chromatin remodeling at key myeloid differentiation loci. Using Tet1/2/3-deficient mice and primary human AML models, we show that ATRA plus ascorbate more effectively induces differentiation, inhibits leukemia stem cell self-renewal in a TET2-dependent manner, and sensitizes AML cells to targeted therapies in vivo leading to improved survival. These findings support the combined use of ATRA and ascorbate as a strategy to enhance TET2 activity for the treatment of myeloid malignancies.

Project description:Enhancing ten-eleven translocation 2 (TET2) activity through genetic or pharmacologic approaches, such as ascorbate supplementation, can slow myeloid malignancy progression. However, ascorbate alone may be insufficient to fully activate TET2 in malignant cells due to pharmacokinetic constraints and the need for chromatin remodeling to enable effective cellular reprogramming. Here, we identify a novel mechanism to enhance TET2 activity via all-trans retinoic acid (ATRA), which induces retinoic acid receptor alpha (RARA)-mediated TET2 transcription in myeloid leukemia cells and synergizes with ascorbate to promote DNA hydroxymethylation and chromatin remodeling at key myeloid differentiation loci. Using Tet1/2/3-deficient mice and primary human acute myeloid leukemia (AML) models, we show that ATRA plus ascorbate more effectively induces differentiation, inhibits leukemia stem cell self-renewal in a TET2-dependent manner, and sensitizes AML cells to targeted therapies in vivo, leading to improved survival. These findings support the combined use of ATRA and ascorbate as a strategy to enhance TET2 activity for the treatment of myeloid malignancies.

Project description:Ascorbate (vitamin C) is an important antioxidant in leaves with multiple functions in photosynthesis and its levels are tightly regulated by light quality. The majority of work to date has focussed on regulation of ascorbate levels via biosynthesis. However, the pathway of ascorbate degradation, which is localised in the apoplast may additionally play a significant role. The degradative pathway begins with ascorbate oxidation by the enzyme ascorbate oxidase (AO) and hence we have examined the impact of manipulation of ascorbate oxidase activity on the content of ascorbate and the acclimation of photosynthesis to changing light levels. Leaf ascorbate content was highly light dependent in Nicotiana tobaccum being double in high compared with low light conditions. In contrast ascorbate oxidase activity was not altered by changing light levels. Transgenic tobacco lines with reduced or enhanced AO activity exhibited no morphological phenotype and photosynthesis under high light was similarly impaired irrespective of the measured AO activity. However further investigation between AO activity and leaf acclimation to changing light intensity revealed a suite of metabolic and transcriptome changes indicating a role for the apoplastic ascorbate pool in chloroplast to nucleus communication. In all genotypes, transcripts associated with ascorbate synthesis and recycling were less abundant following transition from high to low light. However transcripts associated with glutathione recycling, light harvesting, reaction centre function and the Calvin cycle were all increased in abundance. Following the transition from high to low light increases in leaf threonate, an ascorbate degradation product, were proportional to AO activity. A number of chloroplast synthesised amino acids were significantly increased both during high light and following transfer back to LL for 12 h. Similarly, several primary carbohydrates and TCA intermediates were significantly enhanced following high light treatment. In addition to light effects, AO activity had a significant impact on -alanine, aspartate and threonine. Intriguingly, a large number of fatty acids were reduced in antisense AO and wild-type plants immediately after high light stress however the content of these compounds were significantly increased in overexpressing sense lines. We conclude that AO mediated turnover plays an important role in adjusting cellular ascorbate content to photosynthetic need in a fluctuating light environment and that light mediated signals rapidly adjust that the apoplastic ascorbate pool.

Project description:Retinoic acid and ascorbate synergize to suppress myeloid leukemia via TET2 activation [U-937 5hmC-seq]

Project description:Retinoic acid and ascorbate synergize to suppress myeloid leukemia via TET2 activation [MV4-11 5hmC-seq]