Brown AJ , Jones T , Shuttleworth J .

Wellcome Trust

	Figure 1. The synthesis and stability of p40M"l" during oogenesis and meiosis. (A) Proteins from oocytes labeled for 4 h using 35Smethionine were immunoprecipitated with MO15-specific immune serum and analyzed by SDS-PAGE. The relative amounts of labeled p40Mol5 in 30 stage II (lane 1), 20 stage IV (lane 2), five stage VI (lane 3), five dissected stage VI oocyte GVs (lane 4), and five dissected stage VI oocyte cytoplasms (lane 5) are shown. Also shown is protein immunoprecipitated from five labeled stage VI oocytes using preimmune serum (lane 6). (B) Oocytes were labeled for 4 h with 35S-methionine then incubated for 16 h in excess cold methionine. In addition, a number of 35S-methionine labeled stage VI oocytes were incubated for 16 h in excess cold methionine in the presence of progesterone. Some of these progesterone-matured stage VI oocytes were then prickactivated and incubated for a further 90 min. Proteins were then immunoprecipitated and analyzed as described in A. The relative amounts of labeled p40MOl5 in 30 stage II (lane 1), 20 stage IV (lane 2), five stage VI (lane 3), five progesterone-matured stage VI oocytes (lane 4), five prick-activated, mature stage VI oocyte GVs (lane 6), and five dissected stage VI oocyte cytoplasms (lane 7) are shown. The positions of molecular weight markers (in kDa) are indicated.
	Figure 2. Steady-state levels of p40MOlS in oocytes and embryos. (A) Proteins from 25 stage II oocytes (lane 1), 12.5 stage IV oocytes (lane 2), and 2.5 stage VI oocytes were separated by SDS-PAGE and analyzed by Western blotting using M015-specific immune serum and ECL detection (bottom). The relative amounts of p40MOI5 present in each sample were quantitated by densitometry and plotted using an arbitrary scale of 1-100. (B) Proteins from five progesterone-matured stage VI oocytes (lane 1), and five stage 2, 6, 8, 10, 12, 16, 22, and 30 embryos (lanes 2-9) were separated by SDS-PAGE and analyzed by Western blotting using M015-specific immune serum and ECL detection as described in A. The relative amounts of p40MOl5 present in each sample were quantitated by densitometry and plotted using an arbitrary scale of 1-100.
	Figure 3. The relative levels of M015 mRNA in oocytes and embryos. (A) M015 cRNA (lane 1) and 10 ug of total RNA extracted from stage VI oocytes (lane 2), unfertilized eggs (lane 3), and stage 8, 10, 12, 16, and 30 embryos (lanes 4-8) were annealed to a 689-nt 32P-labeled antisense probe from the 5'-end of M015. After RNase digestion the products were analyzed on a 4% acrylamide/urea denaturing gel. Protected fragments of the predicted size of 579 nt and shorter (504 nt and 488 nt) are indicated. (B) Two micrograms of the total RNA preparations used in A from stage VI oocytes (lane 1), unfertilized eggs (lane 2), and stage 8, 10, 12, and 16 embryos (lanes 3-7) were annealed to a 454-nt 2P-labeled antisense ornithine decarboxylase RNA probe. After RNase digestion the products were analyzed on a 4% acrylamide/urea denaturing gel. The protected fragment of the predicted size of 369 nt is indicated.
	Figure 4. Biochemical localization of p40MOlS in stage VI oocytes. Proteins from five dissected stage VI oocyte GVs (lane 1), five dissected stage VI oocyte cytoplasms (lane 2), and five total stage VI oocytes (lane 3) were separated by SDS-PAGE and analyzed by Western blotting using M015-specific immune serum and ECL detection (bottom). The relative amounts of p40Mol` present were quantitated by densitometry and plotted using an arbitrary scale OF 1-100
	Figure 5. Indirect immunofluorescent localization of p4O-MO15 in stage VI oocytes. Acetone-fixed cryosections of stage VI oocytes were incubated with either M015-specific rabbit polyclonal antibody, together with a mouse monoclonal antibody to nucleoplasmin ( A and B) preimmune rabbit serum together with a mouse monoclonal antibody to nucleoplasmin (C and D). Rabbit antibodies were detected using alkaline phosphatase conjugated goat. antirabbit IgG, followed by incubation with Fast Red substrate and fluorescence viewed using a Rhodamine filter (A and C). Mouse antibodies were detected using FITC-conjugated goat antimouse IgG and fluorescence viewed using a fluorescein filter (B and D).
	Figure 6. The activity of p4OMOI5 during oogenesis and resumption of meiosis. (A) p40Mo°5 immunoprecipitates prepared from 25 stage II oocytes (lane 1), 12.5 stage IV oocytes (lane 2), and 2.5 stage VI oocytes (lanes 3 and 4) were incubated with 1 jg of GSTcdk2 (lanes 1-3) or GSTcdk2T16OA (lane 4) and [y_-32P]ATP for 45 min at 23°C. Supematants were recovered, and phosphorylated GSTcdk2 protein was analyzed by SDS-PAGE and autoradiography (bottom). The relative amounts of 32P associated with GSTcdk2 in each reaction were subsequently quantitated by phosphorimage analysis and were plotted on an arbitrary scale of 1-100. (B) Immuno- precipitates were prepared from five dissected stage VI oocyte GVs (lane 1), five dissected stage VI cytoplasms (lane 2), and five total stage VI oocytes (lanes 3-6) using MO15-specific immune serum (lanes 1-4) or preimmune serum (lane 5). The relative amounts of CAK in each sample were assayed as described in A using 1 ,Ag of GSTcdk2 (lanes 1-3 and 5) or GSTcdk2/ T160A (lane 4). (C) p40MO15 immunoprecipitates were prepared from stage VI oocytes before (lane 1) and 0 (lane 2), 2 (lane 3), and 17 h (lane 4) after the addition of progesterone. The relative amounts of CAK in each sample were assayed as described in A using 1 ,ug of GSTcdk2.
	Figure 7. The activity of p4OMOI5 during early embryogenesis. (A) p40M"lS immunoprecipitates were prepared from five unfertilized eggs (lane 1) and five cleaving embryos at 205 (lane 2), 312 (lane 3), 322 (lane 4), 333 (lane 5), 343 (lane 6), and 359 min (lane 7) after fertilization and were incubated with 1 ,g of GSTcdk2 and [_-32P]ATP for 45 min at 23°C. Supematants were recovered, and phosphorylated GSTcdk2 protein was analyzed by SDS-PAGE and autoradiography (bottom). The relative amounts of 32P associated with GSTcdk2 in each reaction were subsequently quantitated by phosphorimage analysis and plotted on an arbitrary scale of 1-100. Mitosis 5 (M5) occurred after 312 min, and mitosis 6 (M6) occurred after 343 min. (B) p40M"OI immunoprecipitates were prepared from five mature stage VI oocytes (lane 1) and five stage 2, 6, 8, 10, 12, 16, and 30 embryos (lanes 2- 8), then assayed for CAK activity as described in A.

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