The phenotype of cct5tf212b is caused by a mutation within cct5. Related to Figure 1.

(A, B) Administration of 100 μM standard control morpholino to 3-dpf-old larvae (morpholino control) did not reduce the birefringence in comparison to larvae that were treated with injection solution (injection control). However, a highly significant reduction in birefringence was detected with 3-dpf-old larvae treated with 100 μM of the translation-blocking morpholino cct5_ex1(+85+110). Data are mean ± SEM. ****p < 0.0001 by one-way ANOVA with Tukey’s post hoc test; n = 10. (C, D) Administration of 200 μM of the splice-altering morpholino cct5_ex5(+187-18) to 3-dpf-old larvae lead to a highly significant reduction in birefringence compared to control larvae that were injected with injection solution (injection control) or larvae that were treated with 200 μM standard control morpholino (morpholino control). Administration of 200 μM cct5_ex5(+187-18) together with 50 ng cct5 transcript significantly increased the birefringence compared to larvae that were injected only with 200 μM cct5_ex5(+187-18). Data are mean ± SEM. ****p < 0.0001 by one-way ANOVA with Tukey’s post hoc test; n = 10. (E) A schematic of the transgenic construct in Tg(cry:mCherry,-1.8cct5:GFP) shows that mCherry expression is controlled by the lens-specific αA-crystallin promoter and GFP is regulated by upstream region of cct5 ranging from -1860 to +24 bp relative to the start codon. (F) At 2 dpf, control injected Tg(cry:mCherry,-1.8cct5:GFP) showed a widespread GFP expression that was abolished in siblings treated with 100 μM cct5_ex1(+85+110); note residual control mCherry in the lens (arrowhead). Representatives of four analyzed larvae per genotype are shown (n = 4 per genotype). (G) Whereas RT-PCR performed with control 3-pdf-old larvae resulted in a 769-bp amplicon, RT-PCR with larvae injected with 200 μM cct5_ex5(+187-18) resulted in two additional amplicons: 688-bp corresponding to a deletion of 81-bp from exon 5 and 853-bp resulting from inclusion of the intron between exons 5 and 6. All amplicons were identified by sequencing. (H) cct5^{hi2972Tg/tf212b} compound heterozygotes displayed a reduction in birefringence that was similar to single cct5^hi2972Tg homozygotes. Data are mean ± SEM. ****p < 0.0001 by student’s t-test; n = 10. (I) Compared to control-injected cct5^hi2972Tg homozygotes, administration of 25 ng cct5 transcript to cct5hi2972Tg homozygotes resulted in a highly significant increase in birefringence. Data are mean ± SEM; ****p < 0.0001 by one-way ANOVA with Tukey’s post hoc test; n = 10. (J) Administration of 50 ng cct5 transcript to cct5^tf212b homozygotes resulted in a highly significant increase in birefringence compared to control-injected cct5^tf212b homozygotes. Data are mean ± SEM. ***p < 0.001 by one-way ANOVA with Tukey’s post hoc test; n = 10.

Affected head musculature and cartilage malformations in cct5^tf212b. Related to Figure 1. (A-C) Representatives of five analyzed larvae per genotype are shown (n = 5 per genotype). (A) At 3 dpf, Z-stack projections of transgenic Tg(-503unc:GFP) larvae reveal that the hyohyoideus (hh) muscles were significantly shortened in cct5^tf212b compared to their siblings. The length of the hyohyoideus muscles were 45 ± 2 μm within cct5^tf212b homozygotes compared to 133 ± 3 μm within siblings (Data are mean ± SEM; p < 0.0001 by student’s t-test; n = 5). (B) Accordingly, Alcian blue and Alizarin red stained 6-dpf-old larvae showed cartilage malformations in cct5^tf212b homozygotes but not in siblings. Label of pharyngeal cartilages: basihyal (bh); ceratohyal (ch); ethmoid plate (e); Meckel’s cartilage (m); palatoquadrate (pq). (C) In contrast to their 6-dpf-old siblings, cct5^tf212b mutants did not close their mouth (marked by asterisk).

In skeletal muscle, mutations within cct genes can lead to enlarged regions of endomysial connective tissue with reduced amount of myofibril. Related to Figures 1 and 2.

(A-G) Cross sections of 3-dpf-old larvae stained for H&E indicate enlarged regions of endomysial connective tissue in cct mutants compared to their siblings. Representatives of a minimum of 6 analyzed larvae per genotype are shown (n > 6 per genotype). (A) Homozygotes of gene trap mutant cct1^hi3564Tg and siblings. (B) Homozygotes of gene trap mutant cct2^hi1269Tg and siblings. (C) Homozygotes of the mutant cct5^tf212b and siblings. (D) Homozygotes of gene trap mutant cct5^hi2972Tg and siblings. (E) Homozygotes of gene trap mutant cct8^mn30Gt and siblings. (F) Homozygotes of null mutant cct3^sa1761 and siblings. (G) Homozygotes of null mutant cct4^-14 and siblings. (H and I) Representatives of 4 analyzed larvae per genotype are shown (n = 4 per genotype). (H) The reduced amount of myofibril in cct3^sa1761 mutants was confirmed in the transgenic background of Tg(acta1:mCherryCaaX) and Tg(acta1:liveact-GFP). (I) According to the reduced level of birefringence, a reduced amount of myofibril in cct4^-14 was visualized by Tg(acta1:mCherryCaaX) and Tg(acta1:liveact-GFP). (J) Regularly spaced actinin-positive Z-bodies of pre-myofibril were detected in siblings as well as in cct4^-14 homozygotes.

TEM micrographs reveal a reduced amount of myofibril in cct mutants. Related to Figures 1 and 2.

(A-E) Sarcomere organization was preserved within all analyzed cct mutants as revealed by EM micrographs of 3-dpf-old larvae. Boxed areas within micrographs of cct mutants are magnified. Arrows point to Z-disk-associated t-tubules and arrowheads notify aggregates. Representatives of a minimum of 3 analyzed larvae per genotype are shown (n > 3 per genotype). (A) The structure of sarcomeres was preserved in cct1^hi3564Tg, however the amount of myofibril was reduced in cct1^hi3564Tg homozygotes. (B) The reduction in the amount of myofibril and the preserved sarcomere organization was also apparent on TEM micrographs of cct2^hi1269Tg. (C) Also in cct5^hi2972Tg mutants, sarcomere organization was preserved, but the amount of myofibril was reduced. (D) cct8^mn30Gt mutants showed a similar myofibril reduction and unaffected sarcomere organization. (E) In cct4^-14 homozygotes the amount of myofibril was reduced and electron-dense aggregates close to Zdisks were documented (arrowheads).

Sarcomeric defects within cct3^sa1761 are not predominantly caused by deficiencies in myosin folding and retina degeneration characterizes cct1^hi3564Tg, cct2^hi1269Tg, cct8^mn30Gt and cct4^-14. Related to Figures 3 and 4. (A) Administration of 10 μM EMD57033, a small molecule that stabilizes and refolds myosin (Radke et al., 2014), significantly increased the birefringence of 3-dpf-old wildtype larvae compared to DMSOtreated control embryos. No significant effect was observed with 1 μM EMD57033 and administration of 100 μM EMD57033 was lethal. Data are mean ± SEM; *p < 0.05 by one-way ANOVA with Tukey’s post hoc test; n = 10. (B) Compared to 3-dpf-old wildtype larvae that were injected with 300 μM standard control morpholino and treated with the control vehicle DMSO at 1 dpf, administration of 300 μM unc45b morpholino and subsequent DMSO treatment led to a highly significant reduction in birefringence. Treatment of unc45b morphants with 10 μM EMD57033 at 1 dpf led to a highly significant amelioration of the birefringence compared to DMSO-treated unc45b morphants. Data are mean ± SEM; ****p < 0.0001 by one-way ANOVA with Tukey’s post hoc test; n = 20. (C) Administration of 10 μM EMD57033 did not significantly (n. s.) ameliorate the birefringence of cct3^sa1761 homozygotes. Data are mean ± SEM; *p < 0.05 by one-way ANOVA with Tukey’s post hoc test; n = 10. (D-G) H&E-stained sections of 3-dpf-old larvae revealed retina degeneration in the following mutants. Representatives of a minimum of 6 analyzed larvae per genotype are shown (n > 6 per genotype). (D) Homozygotes of gene trap mutant cct1^hi3564Tg. (E) Homozygotes of gene trap mutant cct2^hi1269Tg. (F) Homozygotes of gene trap mutant cct8^mn30Gt. (G) Homozygotes of null mutant cct4^-14.

Transgenic marker lines do not reveal a neuronal phenotype within cct5^tf212b. Related to Figure 2.

(A-D) Representatives of a minimum of 3 analyzed larvae per genotype are shown (n > 3 per genotype). At 3 dpf, no marked phenotype was observed with the following transgenic lines labeling distinct neurons: (A) No marked phenotype of cct5^tf212b was observed in the transgenic background of Tg(cmet:eGFP), a marker line for motor neurons (Hall et al., 2007). (B) Similarly, crossing cct5^tf212b into the background of Tg(olig2:eGFP) did not reveal a marked phenotype in the oligodendrocytes of cct5^tf212b (Shin et al., 2003), documented under bright field and fluorescence conditions. (C) Also crossing cct5^tf212b to Tg(ath5:GFP), a marker line for retinal ganglion cells (Masai et al., 2003), did not reveal a neuronal phenotype. (D) Utilizing the Tg(nestin:GFP), which amongst others highlights the neuronal stem cell niche (Kaslin et al., 2009), did not result in a marked phenotype of cct5^tf212b mutants.