Jourdeuil K , Neilson KM , Cousin H , Tavares ALP , Majumdar HD , Alfandari D , Moody SA .

R01 DE016289 NIDCR NIH HHS, R01 DE026434 NIDCR NIH HHS, R01 DE022065 NIDCR NIH HHS

             embryo development

                schizophrenia

	FIGURE 1. Schematic representations of the Sobp and Zmym4 proteins highlighting their different domains. (A) Sobp protein structure adapted from Tavares et al., 2021 highlighting Box2 and Box3 identified by Kenyon et al., 2005. Sobp contains two zinc fingers (ZF1, ZF2), a proline rich domain (PRD), two SUMO-interacting motifs (SIM), and a functional nuclear localization signal (NLS). (B) The Zmym4 protein contains nine zinc finger MYM-containing domains (purple boxes) identified in human ZMYM4 and aligned by sequence homology (Supplementary Figure S3). The areas of sequence homology with Sobp Box2 and Box3 are indicated. Zmym4 contains two putative NLSs, a glucocorticoid-like DNA binding domain (green box), and a C-terminal DUF3504 domain. The NLSs were identified using cNLS mapper (Kojima and Jurka, 2011), the DNA-binding and DUF3504 domains were identified using InterPro (https://www.ebi.ac.uk/interpro/) and the protein structures were generated using DOG2.0.1 (http://dog.biocuckoo.org/). Numbers on the right of each schematic indicate amino acid length of the protein.
	FIGURE 2. Zmym4 does not bind to Six1 or alter the transcriptional activity of Six1, Eya1, or the Six1-Eya1 transcriptional complex in cultured cells. (A) HEK293T cells were transfected with either Myc-tagged Six1, HA-tagged Zmym4, or both and were tested for co-immunoprecipitation (Co-IP) with anti-Myc tagged magnetic beads. In the Co-IP assay (IPanti-Myc), when Six1 was transfected alone, it bound to the Myc-tagged beads (left lane: Zmym4-3HA (), Six1-Myc (+)), whereas when Zmym4 was transfected alone, it did not bind, as expected (middle lane: Zmym4-3HA (+), Six1-Myc ()). When both were transfected, (right lane: Zmym4-3HA (+), Six1-Myc (+)), Six1 was immunoprecipitated by the beads but Zmym4 was not detected in the sample. The flowthrough lanes contained detectable Myc-tagged Six1 but no HA-tagged Zmym4 (left lane), detectable HA-tagged Zmym4 but no Myc-tagged Six1 (middle lane) and detectable Myc-tagged Six1 and HA-tagged Zmym4 (right lane). (B) Luciferase activity of the pGL3-6XMEF-luciferase reporter in HEK293T cells transfected with different combinations of empty vector control, Six1, Eya1, and Zmym4 plasmids. Data were normalized to Renilla expressed by a constitutively active promoter. There was no significant difference between the transcriptional activity of Six1 alone, Zmym4 alone and Six1+Zmym4, between Eya1 alone and Eya1+Zmym4, or between Six1+Eya1 and Six1+Eya1+Zmym4 (ns = p > 0.05).
	FIGURE 3. Altering the levels of Zmym4 in embryos differentially altered the expression of early cranial genes. (A) In the neural border zone, knockdown of Zmym4 by MO injection (A1) resulted in decreased expression of msx1 and tfap2α and broader expression of pax3 on the MO-injected side compared to the control (Ctrl) side of the same embryo. Increased expression of Zmym4 by mRNA injection (A2) caused no change in expression in most embryos. The percentages of embryos that showed “no change” (green), “increased” (pink), and “decreased” (black) expression on the injected side compared to the control side of the same embryo are reported in the bar graphs; the number of embryos examined for each gene is indicated within the bar. (B) In the neural plate, knockdown of Zmym4 (B1) resulted primarily in expanded expression of sox2, sox11, and irx1, whereas increased expression of Zmym4 (B2) caused no change in their expression in most embryos. Bar graphs are as in (A). (C) In the neural crest, knockdown of Zmym4 (C1) resulted primarily in reduced expression of foxd3 and sox9. Increased expression of Zmym4 (C2) primarily increased foxd3 expression, and caused broader sox9 expression in some embryos (∼35%; C2) and reduced expression in others (∼41%; D2). Bar graphs are as in (A). (D) In the preplacodal ectoderm, knockdown of Zmym4 (D1) primarily reduced the expression of six1, irx1, sox9; in contrast, nearly equal numbers of embryos showed no change, expanded or reduced expression of sox11. Increased expression of Zmym4 (D2) showed a minor decrease in six1, whereas for sox11, irx1 and sox9 some embryos showed broader expression while others showed reduced expression. In the D2 embryo images, PPE expression of six1 on mRNA-injected side is slightly reduced compared to control, sox11 is reduced and irx1 is reduced in the anterior placode (arrows). In D2, sox9 is reduced in the otic placode on the injected side (red bar) compared to control (black bar); in C2, sox9 is larger in the otic placode on the injected side (red bar) compared to control (black bar). Bar graphs are as in (A). All embryo images are anterior views with dorsal to the top. np, neural plate. Black scale bars in top right corners = 300 μm.
	FIGURE 4. Loss of Zmym4 caused reduced otic vesicle and branchial arch gene expression. (A) Knockdown of Zmym4 reduced the expression dlx5, sox9, and tbx1 in larval otic vesicles (ov, arrows) and branchial arches (ba, underlined) on the MO-injected side compared to the control (Ctrl) side of the same embryo. Green scale bar in lower right corner indicates 200 μm. (B) The percentages of embryos that showed “no change” (green), “increased” (pink), or “decreased” (black) expression on the MO-injected side compared to the control side of the same embryo; the number of embryos examined for each gene is indicated within the bar. Zmym4 knockdown reduced the OV and BA expression of dlx5 in nearly every embryo, whereas it reduced sox9 or tbx1 expression only in small percentages of embryos. (C) Scatter plot of the number of apoptotic cells counted on the control and MO-injected sides of Zmym4 morphant larvae (n = 15). There was no significant difference (ns = p > 0.05) in the number of apoptotic cells after loss of Zmym4. (D) Blastomeres on the dorsal (D) animal side of cleavage stage embryos were microinjected with mbGFP mRNA ± Zmym4 MOs or Sobp MOs. At tailbud stages, embryos were scored as “migrated” if some fluorescently labeled NC entered a migratory pathway and as “non-migrated” if none of them entered any pathway. Embryo images downloaded from Xenbase (https://www.xenbase.org/xenbase/zahn.do). (E) The percentage of embryos with migrated NC cells in the assay shown in (D) n = the number of embryos analyzed; N = the number of independent trials. n. s. = not significant compared to controls. ***, p < 0.001, Student’s t-test (F) DIC images of typical cranial NC explants when they first adhered to the substrate (t = 0) and 10 h later (t = 10h). Arrowheads indicate Sobp morphant cells that are rounded rather than flattened on the FN substrate. Scale bar = 200 μm. (G) The ratio of the area the NC covered between the start and end of the culture period (end/beginning) (NC dispersal). n. s. = not significant compared to controls (p > 0.05, Student’s t-test). n = the number of embryos analyzed; N = the number of independent trials.
	FIGURE 5. Loss of Zmym4 results in craniofacial cartilage dysmorphologies. (A) Top: ventral views of Alcian blue stained heads from a control tadpole and a sibling Zmym4 morphant (Zmym4 MO). Loss of Zmym4 on the right side of the tadpole resulted in compression of the infrarostral cartilage (I), thickening and shortening of the Meckel’s cartilage (mc), shortening and compression of the ceratohyal cartilage (ch) and reduced size of the ceratobranchial cartilages (cb). The otic capsule (oc) also was reduced in size on the injected side. Bottom: tracing of the craniofacial cartilages to better demonstrate the differences in morphology between the control and morphant infrarostral (orange), Meckel’s (red), ceratohyal (yellow), ceratobranchial (green) and otic capsule (blue) cartilages. Black scale bars in top right corners = 200 μm. (B) Bar graph depicting the percentage of Zmym4 morphants (n = 76) that displayed either “normal” (black), mildly affected (pink), or severely aberrant (green) morphology for each of the five craniofacial cartilages analyzed.

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