Abstract
Myrf is a pleiotropic membrane-bound transcription factor that plays critical roles in diverse organisms, including in oligodendrocyte differentiation, embryonic development, molting, and synaptic plasticity. Upon autolytic cleavage, the Myrf N-terminal fragment enters the nucleus as a homo-trimer and functions as a transcription factor. Homo-trimerization is essential for this function because it imparts DNA-binding specificity and affinity. Recent exome sequencing studies have implicated four de novo MYRF DNA-binding domain (DBD) mutations (F387S, Q403H, G435R, and L479V) in novel syndromic birth defects involving the diaphragm, heart, and the urogenital tract. It remains unknown whether and how these four mutations alter the transcription factor function of MYRF. Here, we studied them by introducing homologous mutations to the mouse Myrf protein. We found that the four DBD mutations abolish the transcriptional activity of the Myrf N-terminal fragment by interfering with its homo-trimerization ability by perturbing the DBD structure. Since the Myrf N-terminal fragment strictly functions as a homo-trimer, any loss-of-function mutation has the potential to act as a dominant negative. We observed that one copy of Myrf-F387S, Myrf-Q403H, or Myrf-L479V, but not Myrf-G435R, was tolerated by the Myrf N-terminal homo-trimer for structural and functional integrity. These data suggest that F387S, Q403H, and L479V cause birth defects by haploinsufficiency, while G435R does so via dominant negative functionality.
Highlights
For myelin regulatory factor (Myrf) to function as a transcription factor, it must undergo auto-cleavage to release its N-terminal fragment from the endoplasmic reticulum (ER) membrane as a homotrimer (4, 5, 22)
It is no wonder that deleterious MYRF mutations implicated in birth defects hit these two core mechanisms
The current study reports that the four mutations mapped to the DNA-binding domain (DBD) (F387S, Q403H, G435R, and L479V) act by disrupting the homo-trimerization of Myrf N-terminal fragment
Summary
Our RT-qPCR analysis revealed that Plp1 was expressed at a significantly lower level in the five mutant cell lines (K592A and the four DBD mutants) than in the wild-type cell line, confirming our conclusion from the luciferase assay that the four mutations cripple the transcriptional activity of Myrf. Myrf-Q403A N-terminal fragment exhibited an electrophoretic mobility that resembles the wild-type pattern (Fig. 5B), suggesting that the Myrf DBD structure somehow tolerates alanine better than histidine and leucine for Q403. If a mutant MYRF allele is expressed at a comparable level to the wild-type one, 12.5% (=0.53), 37.5% (=3 × 0.53), 37.5% (=3 × 0.53), and 12.5% (=0.53) of MYRF N-terminal homo-trimers would contain 0, 1, 2, and 3 mutant fragments, respectively (Fig. 6A).
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