Abstract

Disclosure: S. Parisien-La Salle: None. F. Nobilleau: None. J. Lamontagne: None. S. Éric: None. I. Bourdeau: None.

Introduction: Animal research has been limited in pheochromocytomas and paragangliomas (PPGLs). Recently, Dona et al., described a sdhb mutated zebrafish model by introducing a 13 bp frameshift mutation at the sdhb exon1—intron1 boundary into the zebrafish sdhb gene that recapitulated features of PPGLs. Objective: To generate a new model of mutated sdhb zebrafish to further investigate the underlying metabolic and biochemical perturbations in vivo. Methods: We took advantage of the genetic accessibility of zebrafish embryo to generate loss-of-function model for sdhb using CRISPR/Cas9 technology. Three guide RNAs were designed and microinjected in one-cell stage zebrafish embryos to target the coding sequence of zebrafish sdhb gene. In order to control for the stress brought on by injections, we injected a group of zebrafish with Cas9 endonuclease as a control. At five days post fertilization, mutant and control zebrafish were flash frozen and sent for liquid chromatography mass spectrometry measurements of Krebs cycle metabolites and normetanephrines/metanephrines. All results were normalized to the control groups consisting of wild-type or Cas9 injected larvae. Sdhb expression was analyzed by RT-qPCR in sdhb mutants and wild-type zebrafish larvae. We also monitored survival and heart rate in sdhb mutant zebrafish, compared to wild-type and Cas9. Results: Firstly, we confirmed the significant reduction of sdhb expression in CRISPR-injected larvae compared to wild-type larvae at 5 dpf (0.0613 vs 1.000 p<0.0001). Our metabolic panel showed that succinate was up to 26 times more elevated in sdhb mutants than in wild-type fish extracts (sdhb: 26.51 p<0.0001). Lactate (sdhb: 5.27 p<0.0001), leucine (sdhb: 2.88 p<0.0001), arginine (sdhb: 1.50 p=0.0034) and HMG-CoA (sdhb: 1.36 p=0.0033) were also higher in sdhb mutants. Whereas aspartate (sdhb: 0.244 p<0.0001) and oxidized gluthiatone (sdhb: 0.64 p=0.0011) were significantly lower in sdhb mutants than in wild-types. In regards to functionality, normetanephrine and metanephrine levels were at least four folds higher in sdhb mutants than in Cas9 injected larvaes (4.06 p<0.0001 and 3.42 p<0.0001 respectively). Interestingly, this difference was more noticeable in the fish bathing medium than in larvae tissue extracts, suggesting an increased hormonal excretion (normetanephrines: 4.81 p<0.0001 and metanephrines: 9.40 p<0.0001). Finally, sdhb mutated zebrafish presented with a higher heart rate (148 vs 133 p<0.0001) and reduced lifespan (p<0.0001) when compared to the wild-type/Cas9 group. Conclusion: These findings confirm that the zebrafish is an ideal model for studying PPGLs and their associated genetic defects. Our approach allows the in vivo assessment of a large metabolic panel, opening avenues on new potential clinical metabolic biomarkers in a loss-of-function of the SDHB gene. Ref: Dona M, et al. Endocr Relat Cancer. 2021

Presentation: 6/1/2024