Hwang H , Chen S , Ma M , Divyanshi , Fan HC , Borwick E , Böke E , Mei W , Yang J .

R01 GM140306 NIGMS NIH HHS , R03 AI146900 NIAID NIH HHS , R35 GM131810 NIGMS NIH HHS

             embryo development

	Graphical abstract
	Figure 1. Solubility phase transition of RNA during oocyte maturation (A) Scatter plot shows the pellet to the supernatant ratio in the oocyte (Y-axis) and mature egg (X-axis). I-S transcripts (red) were defined as transcripts enriched by more than 40% in the oocyte pellet fraction and reduced by more than 25% in the pellet fraction after oocyte maturation. I-I transcripts (magenta) were defined as those transcripts enriched by more than 40% in the oocyte pellet fraction, excluding those belonging to the I-S group. S-I transcripts (green) were defined as a more than 2-fold increase in the pellet fraction of mature eggs after oocyte maturation and more than 15% pellet enrichment. (B) Venn diagram shows the overlapping relationship between the fractionation RNA-seq (GEO:GSE199254) and subcellular transcriptomic analysis (GEO:GSE104848). (C) Heat maps show the distribution of S-I, I-I, and I-S transcripts along the animal-vegetal axis.
	Figure 2. Soluble-to-insoluble phase transition of RNA during oocyte maturation (A) MA plot shows the percentage of RNA in the pellet fraction in the mature egg (X-axis) and the ratio between the RNA in the pellet fraction of the egg and that of the oocyte (Y-axis). S-I transcripts are highlighted in the magenta box. (B) Gene ontology analysis demonstrates the top biological processes that are enriched among S-I transcripts. (C) Fractionation RT-qPCR was performed to validate fractionation RNA-seq results. The percentage distribution of ccna1, wee2.S, hmmr.L, parpbp.L, cep152.L, lig4.L, larp1b.S, exd3.L, pif1.L, sox3.S, sema3d.S, ssx2ip.L, espl1.L, wee2.L, ncapd2.S, fbxo43.L, cdc6.L, ccdc18.L, zbtb12.L, kank1.L, ccnb1.2.L, ncbp1.S, eif2ak3.S, dock7.S, ccnb2.L, dbr1.L, and rad21.L in the supernatant and pellet fractions were calculated. (D) The percentage distribution of all markers analyzed in (C) was combined and plotted into the graph. (E) Heat maps show the classification of maternal transcripts based on their degradation during the MZT. Class A transcripts are most rapidly degraded. Class B transcripts are degraded relatively slowly. Class C transcripts are relatively stable during early development. (F) Venn diagram shows the majority of S-I transcripts belong to class A. (G) Heatmap shows the expression of S-I RNAs during early embryonic development.
	Figure 3. Insoluble-to-soluble phase transition of RNA during oocyte maturation (A) MA plot shows the percentage of RNA in the pellet fraction in the oocyte (X-axis) and the ratio between the RNA in the pellet fraction of the egg and that of the oocyte (Y-axis). I-S transcripts are highlighted in the red box. (B) Gene ontology analysis demonstrates the top biological processes that are enriched among I-S transcripts. (C) Protein-protein interaction (PPI) map shows the transcripts selected from a red box in (A). This PPI shows only proteins interacting with at least one or more other proteins. Purple boxes indicate germline transcripts. (D–G) Fractionation RT-qPCR was performed to validate fractionation RNA-seq results. (D) The percentage distribution of germline I-S RNAs, including nanos1, xdazl, pgat, ddx25, grip2, sybu, dnd1, and xvelo1 in the supernatant and pellet fractions, were calculated. (E) The percentage distribution of all germline RNAs analyzed in (D) was combined and plotted into the graph. (F) The percentage distribution of somatic I-S RNAs, including vegT, gdf1, wnt11, elov11.S, wasl.S, and cdr2l.S in the supernatant and pellet fractions, were calculated. (G) The percentage distribution of all somatic I-S RNAs analyzed in (F) was combined and plotted into the graph.
	Figure 4. Turnover of Xvelo1 during oocyte maturation results in the solubilization of germline RNAs (A) Xvelo1 protein is enriched in the insoluble fraction in the oocyte. Oocytes were lysed in NP-40 lysis buffer. After centrifugation, the lysate was separated into the supernatant (S) and pellet (P). Supernatant prepared from 10 oocytes was incubated with an anti-Xvelo1 antibody to enrich Xvelo1 in the soluble fraction. The supernatant, pellet, and IP samples were mixed with SDS sample buffer and subjected to western blotting. (B) The expression of Xvelo1 in the oocytes, ovulated eggs, and embryos at stages 1, 6, 8.5, and 10 was analyzed by western blot. (C) The expression of Xvelo1 during oocyte maturation was analyzed by IF. White arrowheads point to Xvelo1 remaining in the vegetal pole in mature eggs. The scale bars indicate 100 μm. (D) Oocytes and mature eggs of the Dria transgenic frogs, which carry a mitochondria-specific GFP transgene, were stained with an anti-GFP antibody. The scale bars indicate 100 μm. (E) Whole mount in situ results show nanos1 transcripts are located in punctate aggregates in the vegetal of the oocyte. After oocyte maturation, nanos1 transcripts show a diffuse appearance, with only a small number of puncta remaining in the vegetal pole. The scale bars indicate 200 μm. (F and G) Overexpression of Xvelo1 prevents solubilization of germline RNAs after oocyte maturation. Oocytes were injected with 2 ng of myc-Xvelo1 RNA, and cultured for 2 days, followed by progesterone treatment. Fractionation RT-qPCR was performed to assess the phase transition of nanos1, xdazl, pgat, ddx25, dnd1, sybu, and grip2 (F). (G) is the combination of all germline RNAs analyzed in (F). (H) Myc-Xvelo1 RNA injected oocytes were cultured normally or treated with progesterone. Oocytes and mature eggs were fractionated and analyzed for the expression of myc-Xvelo1 and endogenous Hsc70 by western blotting. (I and J) Control and Xvelo1 injected oocytes were used to generate embryos via the host-transfer technique. At stage 11.5, embryos derived from control and Xvelo1 injected oocytes were harvested to assess the expression of nanos1, xdazl, pgat, ddx25, dnd1, sybu, and grip2. (J) is the combination of all markers analyzed in (I). Student t tests were performed. ∗∗ p < 0.01, ∗∗∗ p < 0.001, ∗∗∗∗p < 0.0001.
	Figure 5. Insoluble germline RNAs are resistant to RNase A in vitro (A) Crude oocyte lysate was treated with various doses of RNase A. After RNase A treatment, RNA was extracted for RT-qPCR. The level of nanos1, ddx25, grip2, actin, hsc70, and h2a was measured. RNA from untreated lysate was set as 100%. (B) Schematic diagram shows the procedure for the experiments in (C). (C) Crude oocyte lysate was treated with 12.5 pg/μL RNase A for various amounts of time. Degradation kinetics of germline (nanos1, xdazl, pgat, ddx25, grip2, sybu, dnd1, and xvelo1) and somatic (psma1, odc, gapdh, h2a, actin, hsc70, psme3, and ccna1) RNAs were measured by RT-qPCR. The expression of each germline and somatic RNAs in the oocyte and the mature egg was shown individually. The panel on the right side is the combination of all germline and somatic RNAs in the oocyte and egg. Two-way RM ANOVA tests were performed (oocyte germline vs. oocyte somatic: F(1,7) = 26.8, p = 0.0013; egg germline vs. egg somatic: F(1,7) = 6.24, p = 0.0411; oocyte germline vs. egg germline: F(1,7) = 8.85, p = 0.0207; oocyte somatic vs. egg somatic: F(1,7) = 0.62, p = 0.4544), ∗p < 0.05, ∗∗p < 0.01. (D) Schematic diagram shows the procedure of experiments in (E). (E) Crude lysate was treated with RNase A, separated into the soluble and insoluble fractions, followed by RT-qPCR for nanos1, xdazl, pgat, ddx25, grip2, sybu, dnd1, and xvelo1. Ratio-paired t tests at 1 pg/μL were performed. ∗p < 0.05, ∗∗p < 0.01, ∗∗∗p < 0.001.
	Figure 6. Buc regulates the solubility and stability of germline RNAs in zebrafish (A) Wild-type and bucky ball mutant oocytes were stained with ER-tracker and Mito-tracker. Scale bars on the images for ER trackers indicate 20 μm, and those for Mito trackers indicate 10 μm. (B) Fractionation RT-qPCR was performed to measure the solubility of nanos3, dnd, dazl, ca15b, gra, and vasa in fully grown oocytes from the wild-type fish and bucky ball mutants. The right panel is the combination of all these germline RNAs. (C) The expression of nanos3, dnd, dazl, ca15b, gra, and vasa in 1-cell stage embryos derived from the wild-type and bucky ball mutant females were assessed by RT-qPCR. Student t tests were performed. ∗∗ p < 0.01, ∗∗∗∗p < 0.0001.
	Figure 7. RNA phase transition during zebrafish OET Fractionation RT-qPCR was performed to measure the percentage distribution of ccna1, ccnb1, wee2, dazl, nanos3, gra, ca15b, dnd, and vasa in stage I, stage II/III, and fully grown oocytes, ovulated eggs, and embryos at 2-, 32-, and 512-cell stages.
	S-Fig 1. Validation of I-I RNAs by fractionation RT-qPCR, related to Figure 1. The percentage distribution of I-I RNAs, including rgs2.L, rnu2, thbs1.S, gata6, and bcam.S in the supernatant and pellet fractions were calculated (left panel). The percentage distribution of all I-I RNAs analyzed was combined and plotted into the graph on the right.
	S-Fig 2. Solubility phase transition of RNAs along the animal-vegetal axis, related to Figure 1. Oocytes and mature eggs were dissected into animal and vegetal halves for fractionation RTqPCR. A and B show the percentage distribution of I-S RNAs (nanos1, xdazl, pgat, ddx25, grip2, sybu, dnd1, and xvelo1), S-I RNAs (ccna1, wee2, hmmr.L, parpbp.L, cep152.L, lig4.L, and larp1b.S).
	S-Fig3. RNA phase transition occurs independent of ER remodeling during the OET, related to Figure 1. Control and cytochalasin B (CB)-treated oocytes and mature eggs were subjected to fractionation RT-qPCR. The percentage distribution of I-S RNAs (nanos1, xdazl, pgat, ddx25, grip2, sybu, dnd1, and xvelo1), S-I RNAs (ccna1, wee2, hmmr.L, parpbp.L, cep152.L, lig4.L, larp1b.S, and exd3.L). and I-I RNAs (rgs2.L, rnu2, thbs1.S, gata6, and bcam.S) was analyzed.
	S-Fig 4. Recruitment of maternal RNAs into the insoluble fraction during oogenesis, related to Figure 3. A. The percentage distribution of germline I-S RNAs, including nanos1, xdazl, pgat, ddx25, grip2, sybu, dnd1, and xvelo1 in the supernatant and pellet fractions of stage II, III, IV, and VI oocytes were measured by fractionation RT-qPCR. Among these mRNAs, nanos1, xdazl, pgat, ddx25, and sybu are localized to the vegetal pole through the so-called “early pathway”. The vegetal localization of dnd1 and xvelo1 occurs through the “late pathway”. grip2 can use both the early and late pathways. Thus, it is considered as “intermediate”. B. Whole mount in situ hybridization shows recruitment of ddx25, pgat, nanos1, and dnd1 into the Bb or germ plasm. The scale bars indicate 200 µm. C. Colocalization of ddx25 with Balbiani body in the oocyte. ddx25 was assessed by in situ hybridization using a fluorescent probe. Balbiani body was stained using an anti-Xvelo1 antibody. The scale bars in the upper and lower panels indicate 50 µm and 100 µm, respectively. D. The percentage distribution of I-I RNAs, including rgs2.L, rnu2, thbs1.S, gata6, and bcam.S in the supernatant and pellet fractions of stage II, III, IV, and VI oocytes were measured by fractionation RT-qPCR.
	S-Fig 5. Heatmap shows the change in protein expression across developmental time points, related to Figure 1. From the top to bottom are proteins encoded by S-I, I-S, and I-I RNAs.

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