Fast-twitch myofibrils grow in proportion to Mylpf dosage in the zebrafish embryo.

Muscle cells become stronger by expanding myofibrils, the chains of sarcomeres that produce contraction. Here we investigate how Mylpf (Myosin Light Chain Phosphorylatable Fast) abundance impacts myofibril assembly in fast-twitch muscle. The two zebrafish Mylpf genes (mylpfa and mylpfb) are exclusively expressed in fast-twitch muscle. We show that these cells initially produce six times more mylpfa mRNA and protein than mylpfb. The combined Mylpf protein dosage is necessary for and proportionate to fast-twitch myofibril growth in the embryo. Fast-twitch myofibrils are severely reduced in the mylpfa (-/-) mutant, leading to loss of high-speed movement; however, by persistent slow movement this mutant swims as far through time as its wild-type sibling. Although the mylpfb (-/-) mutant has normal myofibrils, myofibril formation fails entirely in the mylpfa (-/-) ;mylpfb (-/-) double mutant, indicating that the two genes are collectively essential to myofibril formation. Fast-twitch myofibril width is restored in the mylpfa (-/-) mutant by transgenic expression of mylpfa-GFP, mylpfb-GFP, and by human MYLPF-GFP to a degree corresponding linearly with GFP brightness. This correlate is inverted by expression of MYLPF alleles that cause Distal Arthrogryposis, which reduce myofibril size in proportion to protein abundance. These effects indicate that Mylpf dosage controls myofibril growth, impacting embryonic development and lifelong health.