Zhao Y , Shi J , Winey M , Klymkowsky MW .

R01 GM074746 NIGMS NIH HHS , NIH3R01GM074746-06W1 NIGMS NIH HHS

Xla Wt + efhc1 MO (fig.4.e)
Xla Wt + efhc1 MO (fig.S4.a)
Xla Wt + efhc1 MO (fig.S4.b)
Xla Wt + efhc1 MO (fig.S5. b)

	Fig. 1. EFHC1b is associated with various types of cilia. A: An RT-PCR analysis during early development (stages indicated) revealed that EFHC1b RNA levels increase at the onset of gastrulation, confirming previous data from Yanai et al. accessed through the Xenbase website. EF1α RNA was used as an internal control. In situ hybridization reveals the presence of EFHC1b RNA in the ciliated cells of the embryonic epidermis in stage 18 embryos (B) and in a number of different tissues in tailbud stage (stage 33) embryos (C)(CNS: central nervous system; NC: neural crest). D–F: RNAs encoding EFHC1b-GFP and Cetn2-RFP were injected into fertilized eggs and ectodermal explants were generated and analyzed when intact embryos reached stage 24; EFHC1b-GFP (D) was localized to the axonemes and excluded from the basal body regions of the cilia in multiciliated cells (E, F)(see Fig. 2). Scale bar of main image: 20 µm; scale bar for inserts: 10 µm. G–I: The gastrocoele roof plate regions of EFHC1b-GFP RNA injected, stage 19 embryos were dissected and probed with antibodies against GFP (G) and acetylated-α-tubulin (AAT)(H,I-merged image). Individual GRP cilia are indicated by arrowheads. Scale bar of main image: 15 µm; scale bar for inserts: 8 µm. J–L: At stage 26, a section through the neural tube region of an EFHC1b-GFP RNA injected embryos were stained for EFHC1b-GFP (J) and AAT (K, L-merged image); arrowheads indicate primary cilia. Other AAT structures may be neuronal axons or radial glia. Scale bar of main image: 10 µm; scale bar for inserts: 5 µm.
	Fig. 2. The N-terminus of EFHC1b is required for its axonemal localization. A: Plasmids encoding GFP-tagged wild type and deleted forms of the EFHC1b were generated. B: Immunoblot analysis was carried out using an anti-GFP antibody on stage11 embryos injected with RNAs encoding these GFP-tagged polypeptides. C, H: Full length EFHC1b-GFP localizes to axonemes. NTerm-GFP (D, I), δD2-GFP (F, K) and δD3-C-GFP (G, L) were also associated with axonemes, although higher cytoplasmic levels were found compared to the full length protein. The δN-D1-GFP (E, J) polypeptide accumulates to detectable levels in every cell, in contrast to the other mutants and the full-length polypeptides, which appear to accumulate preferentially in ciliated cells. In double labeling studies, fertilized eggs were injected with RNAs encoding EFHC1b-GFP (H–Hʺ), NTerm-GFP (I–Iʺ), δN-D1-GFP (J–Jʺ), δD2-GFP (K–Kʺ), and δD3-C-GFP (L–Lʺ); ectodermal explants were generated and analyzed when intact embryos reached stage 24. Basal bodies were visualized by anti-Xenopus centrin antibody staining (H′, I′, J′, K′, and L′; in no case was there any obvious overlap between the EFHC1 and centrin staining (overlap images in parts Hʺ, Iʺ, Jʺ, Kʺ, and Lʺ). Scale bars: 5 µm.
	Fig. 3. Depletion of EFHC1b results in deficient cilia and multiciliated cell formation. A: The EFHC1b morpholino is efficient for EFHC1b depletion. Embryos were injected with RNAs encoding GFP (150 pgs/embryo) and EFHC1b-GFP match (100 pgs/side) and either control or EFHC1b MO (10 ngs/embryo) and analyzed at stage 11. EFHC1b MO reduced EFHC1b-GFP protein levels, as visualized using an anti-GFP antibody. To examine the effects of reducing EFHC1b levels on the number of ciliated cells (B–D)(scale bar: 100 µm), the basal body density (J), and the number of ciliary axonemes per cell (G–I) (scale bar: 5 µm), both blastomeres of two-cell embryos were injected with membrane-GFP RNA together with either control MO, EFHC1b MO, EFHC1b MO plus EFHC1b-GFP RNA, or EFHC1b MO plus SFRP2 RNA. Membrane-GFP was visualized using an anti-GFP antibody, while anti-acetylated α-tubulin and anti-centrin antibodies were used to visualized cilia and basal bodies, respectively. Quantitation of the EFHC1b morpholino's effect on the number of ciliated cells per cap (E, F) and the basal body density (J)(calculated by dividing the total basal body number per cell by the cell size) are shown as mean±S.D. All the conditions were normalized to control MO (set as 1). N=20 to 25 explants per experimental condition. Significant differences between conditions are marked by horizontal bars (** for p<0.01).
	Fig. 4. EFHC1b plays a role in Wnt signaling. In situ hybridization shows defects (red arrows) in central nervous system (En2) patterning (A, B) and neural crest (Sox9) migration (D, E) in EFHC1b morphants at stage 18 and stage 25, respectively. These phenotypes were rescued by co-injection of EFHC1b-GFP-rescue RNA (C, F). Embryos were injected with either control MO, EFHC1b MO, or EFHC1b MO together with EFHC1b-GFP RNA. All embryos (A–C) were injected with RNA encoding β-galactosidase (red) as a lineage tracer. The loss of neural patterning markers (En2, Krox20, Tubb2b) as well as neural crest markers (Sox9, Twist1) was also rescued by δD3-C-GFP (G). The percentage of embryos that were “abnormal”, that is displayed reduced marker gene expression, was calculated from two independent experiments (N=55 to 60 embryos per condition). H: RNA levels in control and EFHC1b morpholino explants were analyzed at stage 18 using RT-PCR; EFHC1b morphant explants displayed decreased levels of Tubb2 RNA and increased levels of Wnt8a RNA. Levels of BMP4, Noggin and FGF8 RNA were unchanged. I: qPCR analyses (N=3) of control and EFHC1b morphant explants co-injected with EFHC1b-GFP-rescue, Dkk1, or SRFP2 RNAs. Both EFHC1b-GFP-rescue and the two Wnt signaling inhibitors returned all RNAs to control levels. J, K: Embryos were injected with TOPFLASH and FOPFLASH (control) plasmid DNAs (100 pgs/embryo) together with δG-β-catenin RNA (100 pgs/embryo) either alone or together with GFP or EFHC1b-GFP (100 pgs/embryo) RNAs or control, EFHC1b MO (10 ngs/embryo) and EFHC1b MO with SFRP2 RNA. The Y-axis indicates the fold-increase relative to the control TOPFLASH/FOPFLASH value (set equal to 1, N=3). L: qPCR analyses (N=3) of control and EFHC1 morphant explants co-injected with EFHC1b-GFP-rescue, SRFP2, or EFHC1b mutant RNAs on Wnt8 RNA. Besides the EFHC1b-GFP and the Wnt inhibitor SFRP2, injection of δD3-C-GFP RNA (100 pgs/embryo) also returned the Wnt8 RNA to control levels. Significant differences between conditions are marked by horizontal bars; in each case, data are represented as mean±SD, * for p<0.05 and ** for p<0.01. (For interpretation of the references to color in this figure legend, the reader is referred to the web version of this article.)
	Fig. S1. The EFHC family are conserved in eukaryotes. A: Schematic showing the protein domains and motifs within EFHC1 and EFHC2. B: A phylogenetic tree of EFHC1 and EFHC2 protein families across different species. The tree was built by using Phylogeny.fr [S1]. Supplemental reference 1. Dereeper, A., Guignon, V., blanc, G., Audic, S., buffet, S., Chevenet, F., Dufayard, J.-F., Guindon, S., Lefort, V., Lescot, M., et al. (2008). phylogeny.fr: Robust phylogenetic analysis for the non-specialist. Nucleic Acids Res. 36, W465–469.
	Fig. S2. SFRP2 does not rescue the phenotype of cilia formation in EFHC1 morphants. Embryos were injected with membrane-GFP RNA together with either control MO, EFHC1b MO plus SFRP2 RNA. Membrane-GFP was visualized using an anti-GFP antibody, while anti-acetylated α-tubulin and anti-centrin antibodies were used to visualized cilia and basal bodies, respectively. Defect in cilia formation on individual multiciliated cells was not rescued by co-injection of SFRP2 RNA. Scale bar: 5 µm.
	Fig. S3. The density of cells in ectodermal explants is not altered in EFHC1 morphants. Embryos were injected with control MO, EFHC1b MO, and EFHC1b MO plus EFHC1b RNA, in each case using a membrane-GFP as a tracer and cell boundary marker. For each explant, three 100 µmx100 µm regions were examined to determine the overall cell number. Relative total cell numbers are shown as mean±S.D. All the conditions were normalized to control MO (set as 1). N=20–25 per experimental condition.
	Fig. S4. Central nervous system patterning and neural crest migration are impaired in EFHC1 morphants. In situ hybridization shows reduced expression (red arrows) of the CNS markers Krox20 and Tubb2b (A) and the neural crest marker Twist (B) in EFHC1b morphants at stage 18 and stage 25, respectively. These phenotypes were rescued by co-injection of EFHC1b-GFP-rescue RNA. Embryos were injected with either control MO, EFHC1b MO, or EFHC1b MO together with EFHC1b-GFP RNA. All embryos were injected with RNA encoding β-galactosidase RNA (red) as a lineage tracer.
	Fig. S5. Gross morphological effects in EFHC1b morphant embryos. Both blastomeres of two-cell embryos were injected with either 20 ngs/embryo total (A) or EFHC1 morpholino (B); embryos that passed successfully through gastrulation were fixed at stage 35. Compared to uninjected (not shown) or control MO injected embryos (A), EFHC1 MO injected embryos typically displayed a noticeable kink and were visibly smaller (B).
	efhc1 (EF-hand domain (C-terminal) containing 1) gene expression in Xenopus laevis embryo, assayed via in situ hybridization, NF stage 18, lateral view, anterior right, dorsal up.
	efhc1 (EF-hand domain (C-terminal) containing 1) gene expression in Xenopus laevis embryo, assayed via in situ hybridization, NF stage 32, lateral view, anterior right, dorsal up.

Araki, Centrosome protein centrin 2/caltractin 1 is part of the xeroderma pigmentosum group C complex that initiates global genome nucleotide excision repair. 2001, Pubmed

Araki, Centrosome protein centrin 2/caltractin 1 is part of the xeroderma pigmentosum group C complex that initiates global genome nucleotide excision repair. 2001, Pubmed
Bai, DNA variants in coding region of EFHC1: SNPs do not associate with juvenile myoclonic epilepsy. 2009, Pubmed
Blaya, Preliminary evidence of association between EFHC2, a gene implicated in fear recognition, and harm avoidance. 2009, Pubmed
Bradley, Different activities of the frizzled-related proteins frzb2 and sizzled2 during Xenopus anteroposterior patterning. 2000, Pubmed , Xenbase
Brooks, In vivo investigation of cilia structure and function using Xenopus. 2015, Pubmed , Xenbase
Brown, Cilia and Diseases. 2014, Pubmed
Chu, The appearance of acetylated alpha-tubulin during early development and cellular differentiation in Xenopus. 1989, Pubmed , Xenbase
Cunningham, Human TREX2 components PCID2 and centrin 2, but not ENY2, have distinct functions in protein export and co-localize to the centrosome. 2014, Pubmed
Dent, A whole-mount immunocytochemical analysis of the expression of the intermediate filament protein vimentin in Xenopus. 1989, Pubmed , Xenbase
Dubaissi, Embryonic frog epidermis: a model for the study of cell-cell interactions in the development of mucociliary disease. 2011, Pubmed , Xenbase
Ferkol, Ciliopathies: the central role of cilia in a spectrum of pediatric disorders. 2012, Pubmed
Gerdes, Disruption of the basal body compromises proteasomal function and perturbs intracellular Wnt response. 2007, Pubmed
Glinka, Dickkopf-1 is a member of a new family of secreted proteins and functions in head induction. 1998, Pubmed , Xenbase
Gu, A new EF-hand containing gene EFHC2 on Xp11.4: tentative evidence for association with juvenile myoclonic epilepsy. 2005, Pubmed
Hildebrandt, Ciliopathies. 2011, Pubmed
Ikeda, Rib72, a conserved protein associated with the ribbon compartment of flagellar A-microtubules and potentially involved in the linkage between outer doublet microtubules. 2003, Pubmed
Ikeda, The mouse ortholog of EFHC1 implicated in juvenile myoclonic epilepsy is an axonemal protein widely conserved among organisms with motile cilia and flagella. 2005, Pubmed
Karpinka, Xenbase, the Xenopus model organism database; new virtualized system, data types and genomes. 2015, Pubmed , Xenbase
Katano, The juvenile myoclonic epilepsy-related protein EFHC1 interacts with the redox-sensitive TRPM2 channel linked to cell death. 2012, Pubmed
Kilburn, New Tetrahymena basal body protein components identify basal body domain structure. 2007, Pubmed
Kim, Rab11 regulates planar polarity and migratory behavior of multiciliated cells in Xenopus embryonic epidermis. 2012, Pubmed , Xenbase
King, Axonemal protofilament ribbons, DM10 domains, and the link to juvenile myoclonic epilepsy. 2006, Pubmed
Li, Chibby cooperates with 14-3-3 to regulate beta-catenin subcellular distribution and signaling activity. 2008, Pubmed
Liu, Ciliopathy proteins regulate paracrine signaling by modulating proteasomal degradation of mediators. 2014, Pubmed
Merriam, Cytoplasmically anchored plakoglobin induces a WNT-like phenotype in Xenopus. 1997, Pubmed , Xenbase
Pal, Commentary: Pathogenic EFHC1 mutations are tolerated in healthy individuals dependent on reported ancestry. 2015, Pubmed
Park, The key role of transient receptor potential melastatin-2 channels in amyloid-β-induced neurovascular dysfunction. 2014, Pubmed
Rossetto, Defhc1.1, a homologue of the juvenile myoclonic gene EFHC1, modulates architecture and basal activity of the neuromuscular junction in Drosophila. 2011, Pubmed
Rossi, Genetic compensation induced by deleterious mutations but not gene knockdowns. 2015, Pubmed
Sahni, Widespread macromolecular interaction perturbations in human genetic disorders. 2015, Pubmed
Setter, Tektin interactions and a model for molecular functions. 2006, Pubmed
Shi, Snail2 controls mesodermal BMP/Wnt induction of neural crest. 2011, Pubmed , Xenbase
Shi, Centrin-2 (Cetn2) mediated regulation of FGF/FGFR gene expression in Xenopus. 2015, Pubmed , Xenbase
Shi, Chibby functions in Xenopus ciliary assembly, embryonic development, and the regulation of gene expression. 2014, Pubmed , Xenbase
Steinman, An electron microscopic study of ciliogenesis in developing epidermis and trachea in the embryo of Xenopus laevis. 1968, Pubmed , Xenbase
Stogmann, Idiopathic generalized epilepsy phenotypes associated with different EFHC1 mutations. 2006, Pubmed
Subaran, Pathogenic EFHC1 mutations are tolerated in healthy individuals dependent on reported ancestry. 2015, Pubmed
Suzuki, Sequential expression of Efhc1/myoclonin1 in choroid plexus and ependymal cell cilia. 2008, Pubmed
Suzuki, Efhc1 deficiency causes spontaneous myoclonus and increased seizure susceptibility. 2009, Pubmed
Suzuki, Mutations in EFHC1 cause juvenile myoclonic epilepsy. 2004, Pubmed
Takemaru, Fine-tuning of nuclear-catenin by Chibby and 14-3-3. 2009, Pubmed
Takemaru, Chibby, a nuclear beta-catenin-associated antagonist of the Wnt/Wingless pathway. 2003, Pubmed
Wallingford, Strange as it may seem: the many links between Wnt signaling, planar cell polarity, and cilia. 2011, Pubmed , Xenbase
Weiss, Identification of EFHC2 as a quantitative trait locus for fear recognition in Turner syndrome. 2007, Pubmed
Werner, Understanding ciliated epithelia: the power of Xenopus. 2012, Pubmed , Xenbase
Yamakawa, Re-evaluation of myoclonin1 immunosignals in neuron, mitotic spindle, and midbody--nonspecific? 2013, Pubmed
Yanai, Mapping gene expression in two Xenopus species: evolutionary constraints and developmental flexibility. 2011, Pubmed , Xenbase
Zhang, The beta-catenin/VegT-regulated early zygotic gene Xnr5 is a direct target of SOX3 regulation. 2003, Pubmed , Xenbase
Zhang, Unexpected functional redundancy between Twist and Slug (Snail2) and their feedback regulation of NF-kappaB via Nodal and Cerberus. 2009, Pubmed , Xenbase
Zhang, An NF-kappaB and slug regulatory loop active in early vertebrate mesoderm. 2006, Pubmed , Xenbase
de Nijs, Juvenile myoclonic epilepsy as a possible neurodevelopmental disease: role of EFHC1 or Myoclonin1. 2013, Pubmed
von Podewils, Predictive value of EFHC1 variants for the long-term seizure outcome in juvenile myoclonic epilepsy. 2015, Pubmed