Styxl2 regulates sarcomere integrity during zebrafish muscle development.

(A) A schematic of mouse Styxl2 protein. DSPc (red): dual-specificity phosphatase, catalytic domain. The numbers denote the positions of various amino acids in mouse Styxl2 including Ser (S)-225. (B) The expression of Styxl2 protein in different mouse tissues. 100 μg of soluble mouse tissue lysates were subjected to Western blot analysis. GAPDH: glyceraldehyde-3-phosphate dehydrogenase. SM: skeletal muscles. (C) The expression of Styxl2 protein in C2C12 myoblasts before and after differentiation in culture. MHC: myosin heavy chain. (D) Zebrafish zygotes were either mock-injected or injected with a Styxl2-specific morpholino (MO). Sarcomeres in muscles at 48 hpf were revealed by transmission electron microscopy (TEM). Representative images were shown. Scale bar: 500 nm. (E) Sarcomeres in fast and slow muscles of zebrafish embryos at 24 hpf were revealed by immunostaining using specific antibodies as indicated. Ctrl: control (non-treated); MO: Styxl2-morpholino-treated. The nuclei of slow and fast muscle fibers were counter-stained with an anti-Prox1 antibody and DAPI, respectively. Scale bar: 10 μm.

Candidate genes regulated by both Jak1 and Stat1.

Selected candidate genes targeted by both si-Jak1 and si-Stat1 were shown. The fold change was determined by the relative levels of a gene in cells treated with si-Jak1 or si-Stat1 over that in control cells. Genes with fold change > 1.5 for si-Jak1 and > 2 for si-Stat1 were listed in this table. Genes with positive fold change are up-regulated (positive value), while those with negative fold change are down-regulated. P Stage and D Stage denote the proliferation stage (GM 24h) and early differentiation stage (DM 12h), respectively.

Conditional deletion of mouse Styxl2 leads to defective sarcomeres in striated muscles.

(A) The expression of Styxl2 protein in skeletal muscles of wild-type (+/+), heterozygous (+/−) and Styxl2 knockout (KO) (−/−) (driven by EIIA-Cre) mice. Soluble tissue lysates from limbs of E14.5 mouse embryos were subjected to Western blot analysis. N.S.: non-specific. (B) E14.5 embryos of control (Ctrl) and EIIA-Cre; Styxl2f/f KO mice. *: edema was found in some Styxl2 KO foetuses. (C) The sarcomere structures of cardiomyocytes in the heart of E14.5 embryos from control and EIIA-Cre; Styxl2f/f KO mice were revealed by TEM. Scale bar: 1 μm. (D) The expression of Styxl2 protein in skeletal muscles of control (Ctrl) and Styxl2 CKO P1 mice. (E) The new-born pups (P1) from control (Ctrl) and Pax7Cre/+; Styxl2f/f KO mice (CKO). (F) Lung sections of control and Styxl2 CKO P1 mice. Scale bar: 50 μm. (G) The sarcomere structure of diaphragm muscles from control (Ctrl) and Styxl2 CKO P1 mice revealed by TEM. Scale bar: 1μm.

Styxl2 is not required for sarcomere maintenance but involved in de novo sarcomere assembly in adult muscles.

(A) The schematic to assess the role of Styxl2 in sarcomere maintenance in adult muscles. TMX: tamoxifen. (B) Styxl2 protein levels in Ctrl and MF-iKO mouse gastrocnemius muscles used for force test. The band intensity of Styxl2 was quantified by ImageJ. (C, D) The twitch and tetanic force generated by gastrocnemius muscles of three Ctrl and four MF-iKO mice were measured. In (A-D), Ctrl: Styxl2f/f mice; MF-iKO: Tg: HSA-MerCreMer; Styxl2f/f mice. (E) The schematic to assess the role of Styxl2 in de novo sarcomere assembly in adult muscles. CTX: cardiotoxin. (F) Styxl2 protein levels in regenerated gastrocnemius muscles used for force test. N.S.: non-specific. The band intensity of Styxl2 was quantified. (G, H) Twitch and tetanic force by regenerated gastrocnemius muscles were measured from four pairs of control and SC-iKO mice. (I) TEM images of the muscle used for force generation test. Scale bar: 500 nm. (J) Quantification of sarcomere length in (I). TEM images from three pairs of mice were examined and the length of 3-5 sarcomeres from each mouse was measured. In (E-J), Ctrl: Pax7CreERT2/CreERT2 mice; SC-iKO: Pax7CreERT2/CreERT2; Styxl2f/f mice. n.s.: not significant. *, p-value < 0.05. ***, p-value < 0.001.

Styxl2 binds to non-muscle myosin IIs.

(A) The schematic of the fusion protein Styxl2-BirA*-HA. (B) The workflow of sample preparation for BioID. (C) Enriched (with Enrichment score >1) biotinylated proteins in cells expressing Styxl2-BirA*-HA relative to that in control cells were identified by mass spectrometry followed by Gene Ontology (GO) analysis. Myofibril-related terms were shown. (D) C2C12 cells were harvested after 2 days in DM and the soluble whole cell lysates were subjected to immunoprecipitation (IP) using either an anti-MEF2A (negative control) or an anti-Styxl2 antibody. The endogenous Myh9 or Myh10 was detected by Western blot. (E) The schematic showing the domains of non-muscle myosin IIs (NM II). (F) HEK 293T cells were transfected with Flag-Styxl2 (black arrow) together with HA-NM II-head (red arrowheads) or HA-NM II-tail (black arrowheads). The soluble whole cell lysates were subjected to IP with an anti-Flag antibody and the co-immunoprecipitated proteins were detected by Western blot.

Styxl2 protein levels inversely correlates with that of non-muscle myosin IIs.

(A) Protein levels of Styxl2 and non-muscle myosin IIs in skeletal muscles of wild-type mice of different ages were determined by Western blot. (B) Protein levels of Styxl2 and non-muscle myosin IIs in skeletal muscles of control and Styxl2 CKO P1 mice were determined by Western blot. (C) Relative ratios of non-muscle myosin II protein levels in control and Styxl2 CKO P1 mice were quantified by ImageJ based on the data from four (for Myh9) or five (for Myh10) sets of Western blots. (D) Protein levels of Styxl2 and non-muscle myosin IIs in regenerating tibialis anterior muscles were determined by Western blot. The experiments were done for four times with similar results and a representative gel was shown. The protein levels of NM IIs in 10 dpi muscles revealed by Western blot were quantified in the right panel. Ctrl: Pax7CreERT2/CreERT2 mice; SC-iKO: Pax7CreERT2/CreERT2; Styxl2f/f mice; dpi: days post-injury. (E) Zebrafish zygotes were separately injected with the following morpholinos (MO): control (Ctrl-MO), Styxl2-MO, and mixed morpholinos targeting both Styxl2 and Myh10 (dMO). At 48 hpf, zebrafishes were poked by a fine needle and their responses were recorded. Quantification of responses of zebrafish to needle touch was shown. In each group, at least 8 zebrafishes were tested and the percentage of zebrafishes responding to needle touch was calculated. Each dot represents one group of experiment. (F) Zebrafishes from each condition in (E) were subjected to immunostaining for α-actinin to visualize sarcomere structures. Representative images were shown. The inset at the top right corner of each image shows the actinin intensity along the yellow line. Scale bar: 10 μm. *, p-value < 0.05. **, p-value < 0.01. ****, p-value < 0.0001.

The DSPc domain of Styxl2 is dispensable for degradation of non-muscle myosin IIs.

(A) DNA constructs encoding Myh9, Styxl2 or Mst1 (negative control) were co-expressed in C2C12 cells. Soluble whole cell extracts were subjected to Western blot analysis. OE: overexpression. (B) The schematic shows the truncated fragments of Styxl2 protein. The red blocks indicate the DSPc domain of Styxl2. HEK 293T cells were transfected with different plasmids as indicated. 24 h after transfection, cells were harvested and soluble whole cell extracts were subjected to Western blot analysis. The arrow indicates the head domain of Myh9, and the arrowhead indicates Styxl2 missing the N-terminal 509 aa (Styxl21′N509). Mst1: negative control. N.S.: non-specific. (C) Zebrafish zygotes were injected with various morpholinos as indicated with or without the co-injected Styxl2 mRNAs. zStyxl2FL: the full-length fish Styxl2 mRNA; zStyxl21′N493: the truncated fish Styxl2 mRNA missing the 5’ region encoding the N-terminal 493 aa. Representative α-actinin immunofluorescent images were shown. The number in numerator at the top left corner of each image represents fish embryos showing normal α-actinin staining pattern, while that in denominator represents the total number of embryos examined. The inset at the top right corner of each image shows the actinin intensity along the yellow line. Scale bar: 10 μm.

The Styxl2-mediated degradation of non-muscle myosin IIs is autophagy dependent.

(A) Plasmids encoding Myh9, Styxl2 or Mst1 (negative control) were co-expressed in C2C12 cells together with various siRNAs as indicated. Soluble whole cell extracts were subjected to Western blot analysis. OE, overexpression. N.S.: non-specific. The protein level of Myh9 was quantified at the bottom panel. *, p-value < 0.05. (B) HEK 293T cells were transfected with various constructs as indicated. Various inhibitors of the autophagy-lysosome pathway (50 μM LY294002, 100 μM Chloroquine, 100 nM BafA1, 20 mM NH4Cl) were added to the cell culture 6 h before harvest. OE, overexpression. (C) HEK 293T cells were co-transfected with the plasmids as indicated. 18 h later, 100 nM of BafA1 was added to the culture medium. After another 6 h, the soluble whole cell lysates were subjected to immunoprecipitation (IP) with an anti-Myc antibody and the immunoprecipitated proteins were further analysed by Western blot (WB). The red arrow indicates Flag-Styxl2. (D) The schematic showing that Styxl2 promotes sarcomere assembly by binding to and targeting non-muscle myosin IIs for degradation, which facilitates their eventual replacement by muscle myosin II during sarcomere maturation.