Role of succinate in acute myeloid leukemia (Transfer to Tromsø)
The aim of this project is to study the contribution of succinate in acute myeloid leukemia (AML) development and to investigate possible treatments. Results will lead to advances in AML knowledge and potential patient treatment improvement. To explore the role of succinate in various aspects of hematopoetic stem cell (HSC) biology, we will assess the impact of succinate injections in the hematopoietic system of adult healthy and leukemic mice. Mice models knockout for succinate receptor (McCreath et al., 2015, Diabetes) are needed to examine whether Sucnr1 aids AML development and whether it could be a new therapeutic target. 5-fluorouracil (5-FU) challenge in C57BL/6 and Sucnr1 -/- mice will allow us to study whether succinate induces changes in HSC proliferation and self-renewal under stress hematopoiesis (Cheng T et al., 2000, Science). Despite mild toxicity of 5FU (Sanchez-Aguilera et al., 2014, Cell Stem Cell), this is an approved cancer treatment regularly used in humans. Our findings will reveal for the first time the contribution of SUCNR1 receptor in bone marrow (BM) microenvironment. Mice will be euthanized when they show early signs of sickness to prevent unnecessary suffering and a Kaplan-Meier curve will describe survival characteristics.
C57BL/6, Sucnr1 -/- and Sucnr1 tomato mice will be used as recipient of control and mutant BM cells from Mx1-Cre NRAS-G12D mice. Recipient mice with a specific deletion of the Sucnr1 gene in the BM microenvironment will also be used as recipients of transplantation to understand the specific role of this receptor in the BM microenvironment. Conversely, succinate receptor deletion will be performed selectively in the hematopoietic system to understand the cell-autonomous effect in leukemia. Potential mediation of the phenotype through S100A8/A9 will be demonstrated by the use of S100A8/A9 deficient mice. Prior to transplantation, recipient mice need to be whole body irradiated. Total whole body irradiation is used in the field of blood stem cell function and cancer (for more information: http://www.bu.edu/orccommittees/iacuc/policies-and-guidelines/irradiation-of-rodents/). It allows to kill proliferating blood cells without significant damage of resting tissues, and simultaneously promotes proliferation of transplanted cells. Mice might suffer from a temporary loss of their body weight up to 25% . Animals should be on their way to recovery at day 21 (cut-off weight loss 15%), and recovered at day 30 (cut-off weight loss 10%). All mice will be transplanted after irradiation, done in two half doses to reduce adverse effects. The results will provide a novel platform for more efficient therapies against AML, one of the most aggressive and frequent blood disorder that affects adults and children. It is not the goal of this study to analyze terminal stages. The number of animals will be kept in the minimum necessary (n=1671 total) to obtain statistically meaningful results, using them in the most efficient way possible.
C57BL/6, Sucnr1 -/- and Sucnr1 tomato mice will be used as recipient of control and mutant BM cells from Mx1-Cre NRAS-G12D mice. Recipient mice with a specific deletion of the Sucnr1 gene in the BM microenvironment will also be used as recipients of transplantation to understand the specific role of this receptor in the BM microenvironment. Conversely, succinate receptor deletion will be performed selectively in the hematopoietic system to understand the cell-autonomous effect in leukemia. Potential mediation of the phenotype through S100A8/A9 will be demonstrated by the use of S100A8/A9 deficient mice. Prior to transplantation, recipient mice need to be whole body irradiated. Total whole body irradiation is used in the field of blood stem cell function and cancer (for more information: http://www.bu.edu/orccommittees/iacuc/policies-and-guidelines/irradiation-of-rodents/). It allows to kill proliferating blood cells without significant damage of resting tissues, and simultaneously promotes proliferation of transplanted cells. Mice might suffer from a temporary loss of their body weight up to 25% . Animals should be on their way to recovery at day 21 (cut-off weight loss 15%), and recovered at day 30 (cut-off weight loss 10%). All mice will be transplanted after irradiation, done in two half doses to reduce adverse effects. The results will provide a novel platform for more efficient therapies against AML, one of the most aggressive and frequent blood disorder that affects adults and children. It is not the goal of this study to analyze terminal stages. The number of animals will be kept in the minimum necessary (n=1671 total) to obtain statistically meaningful results, using them in the most efficient way possible.
Etterevaluering
The Norwegian Food Safety Authority must retrospectively assess all severe experiments.
Begrunnelse for etterevalueringen
Sucnr1 restricts hematopoiesis partially via a direct action on HSPCs by modulating S100a8/a9 and its downregulation in AML patients is associated with poorer outcome. It might be used in the future as a marker for personalized medicine in some patients, and the maximum therapeutic potential of targeting this pathway still needs to be uncovered in future work in 30992.
These data are currently in revision in Nature Communications.
Our further observations suggest that Sucnr1 regulates HSPCs indirectly through their microenvironment. This will be the subject of future work in 30992.
Animals with actual severity were animals terminated because of humane endpoint or found dead. Severity as expected.
We always use in vitro and ex vivo experiments when appropriate, before performing in vivo experiments; transplantation is only performed by experienced researchers; and animals are followed up closely with use of score sheets. As a recent improvement already reported, the conditions are kept sterile starting one week before performing the transplant in this and all our current FOTS. Another improvement which started after our move to UiO from UiT is tunnel handling, which has greatly reduced stress-associated behavior and improved the welfare of all our animals in all our FOTS. This together with breeding routines in KPM UiO (bigger cages, no separation of male...) are resulting in bigger litters from breedings.
These data are currently in revision in Nature Communications.
Our further observations suggest that Sucnr1 regulates HSPCs indirectly through their microenvironment. This will be the subject of future work in 30992.
Animals with actual severity were animals terminated because of humane endpoint or found dead. Severity as expected.
We always use in vitro and ex vivo experiments when appropriate, before performing in vivo experiments; transplantation is only performed by experienced researchers; and animals are followed up closely with use of score sheets. As a recent improvement already reported, the conditions are kept sterile starting one week before performing the transplant in this and all our current FOTS. Another improvement which started after our move to UiO from UiT is tunnel handling, which has greatly reduced stress-associated behavior and improved the welfare of all our animals in all our FOTS. This together with breeding routines in KPM UiO (bigger cages, no separation of male...) are resulting in bigger litters from breedings.