First published online February 20, 2009
doi: 10.1242/10.1242/dev.031815
Development 136, 923-932 (2009)
Published by The Company of Biologists 2009
An essential role for the RNA-binding protein Smaug during the Drosophila maternal-to-zygotic transition
Beatrice Benoit1,2,
Chun Hua He3,4,
Fan Zhang1,
Sarah M. Votruba3,
Wael Tadros3,4,
J. Timothy Westwood5,
Craig A. Smibert3,6,
Howard D. Lipshitz3,4 and
William E. Theurkauf1,*
1 Program in Molecular Medicine and the Program in Cell Dynamics, University of
Massachusetts Medical School, 377 Plantation Street, Worcester, MA 01605,
USA.
2 Institut Jacques Monod, UMR7592, 2 place Jussieu, 75251 Paris, Cedex 05,
France.
3 Department of Molecular Genetics, University of Toronto, 1 King's College
Circle, Toronto, Ontario M5S 1A8, Canada.
4 Program in Developmental and Stem Cell Biology, Research Institute, Hospital
for Sick Children, TMDT Building, 101 College Street, Toronto, Ontario M5G
1L7, Canada.
5 Department of Cell and Systems Biology and Canadian Drosophila
Microarray Centre, University of Toronto, Mississauga, Ontario L5L 1C6,
Canada.
6 Department of Biochemistry, University of Toronto, 1 King's College Circle,
Toronto, Ontario M5S 1A8, Canada.
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Fig. 1. Replication checkpoint activation during the MZT. The DNA
replication checkpoint is required for increases in interphase length during
syncytial blastoderm divisions 11-13. (A) Interphase length was assayed
by injection of rhodamine-conjugated Tubulin and time-lapse confocal imaging.
Embryos mutant for smg, like grp replication checkpoint
mutants, do not show increases in interphase length during the syncytial
blastoderm divisions. (B) Replication checkpoint function was assayed
by co-injection of rhodamine-Tubulin and aphidicolin or carrier control. In
wild-type embryos, aphidicolin induced progressively longer interphase delays
during cycles 11-13. By contrast, smg mutants showed only minimal
interphase delays in response to aphidicolin, and the delays did not increase
with division cycle number. Each bar represents the mean interphase length (in
minutes) with standard deviations. The number of individual embryos scored is
given in brackets.
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Fig. 2. Smaug is required for zygotic transcription during the MZT.
(A) Microarray analysis of zygotic gene expression in 2- to 3-hour-old
wild-type (wt) and smg mutant embryos. Expression is
relative to mature, stage 14 oocytes, which contain the full maternal pool of
mRNA. Maternal genes that are not transcribed at the MZT represent  80% of
transcripts in early embryos, and are not shown. Class I zygotic genes are not
present in oocytes (not colored) and show high levels of expression in 2- to
3-hour-old embryos. One-hundred and forty-two of the 166 Class I genes
required Smaug for zygotic expression. Class II genes produce maternal
transcripts that are stable in unfertilized eggs and show significantly
increased expression in 2- to 3-hour-old post-fertilization embryos.
Three-hundred and fifty-eight of 395 Class-II genes require Smaug for zygotic
expression. Class III genes produce maternal transcripts that are degraded and
then re-expressed in 2-3 hour post-fertilization embryos. Sixty-five of 408
Class III genes require Smaug for expression. (B) Serine 2
phosphorylation of the RNA polymerase II CTD is linked to active
transcription. Western blots reveal a dramatic increase in ser 2
phosphorylation between 2 and 4 hours of embryogenesis in wild type
(wt) and mnk grp, but not in grp, smg or
mnk; smg mutants. For each genotype, lane 1 shows 0- to
1-hour-old embryos, lane 2 shows 1- to 2-hour-old embryos, lane 3 shows 2- to
3-hour-old embryos and lane 4 shows 3- to 4-hour-old embryos. For each
genotype, the top panel shows the hyperphosphorylated (II0, Ser2-P) and the
hypophosphorylated (IIa) forms, detected with an anti-RNA polII (ARNA3). The
middle panel shows phosphorylation on Ser2 (II0) detected using the
phospho-epitope specific H5 antibody. The bottom panel shows  -Tubulin,
which was used as a loading control. (C) Northern blots for miR-6,
miR-286 and miR-3 revealed a large increase in wild-type 2- to
4-hour-old embryos, whereas expression was not detected smg mutants.
(D) Heat map showing the behavior of 406 of the 410
miR-309-dependent maternal mRNAs (from
Bushati et al., 2008 ) in
embryos from wild-type and smg-mutant females relative to wild-type
stage 14 oocyte reference RNA. These transcripts are unstable (green) in wild
type, whereas almost 85% are stabilized in smg mutants.
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Fig. 3. Maternal mRNA degradation is independent of the replication
checkpoint. Embryos mutant for smg are defective in replication
checkpoint activation and maternal transcript destruction. (A-L)To
determine whether checkpoint defects lead to a block in maternal transcript
destruction, grp checkpoint mutant embryos were assayed for maternal
cyclin A (A-F) and cyclin B (G-L) mRNA expression by
whole-mount in situ hybridization. In wild-type controls, both transcripts are
expressed in syncytial blastoderm embryos (S; A,G) and are degraded
during interphase of cycle 14 (14 D,J). The smg mutation
blocks destruction of these transcripts (C,F,I,L), but the grp
mutations does not (B,E,H,K). Embryos are orientated with their anterior pole
facing leftwards. S, syncytial blastoderm; 14, cycle 14. Scale bar: 100
µm.
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Fig. 4. Smaug protein expression during early embryogenesis. (A)
Smaug protein expression in wild-type ovaries and embryos. Lane 1, ovary (o);
lanes 2-9, embryos were fluorescently labeled, hand selected for specific
division cycles (cycles indicated above lane) and subjected to western
blotting (E and L indicate early and late interphase 1); lanes 10-17, western
blots of pooled embryos aged 0 to 1 hour (1), 1 to 2 hours (2), 2 to 3 hours
(3) and 3 to 4 hours (4); lanes 10-13 are fertilized embryos; lanes 14-17 are
activated unfertilized eggs (unf). -Tubulin is used as a loading
control. (B) Quantification of Smaug expression relative to
-Tubulin for each of the lanes shown in A. In fertilized embryos, Smaug
protein levels increase progressively through the early cleavage divisions,
peak during cycles 11-13, and decline rapidly during interphase 14. In
unfertilized eggs, the protein accumulates rapidly through the first 3 hours
post egg deposition, and persists for 4 hours (lanes 14-17).
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Fig. 5. Generating a Smaug protein gradient. (A) Schematic
representation of the UAS-smg-bcd transgene (USB). The yeast
upstream activator sequence (UAS), Smaug coding sequence (Smaug ORF,
bold line) and bcd 3' UTR (3'-UTR-bcd)
are indicated. (B,C) Immunolocalization of Smaug protein in
embryos derived from wild-type (wt) and smg females
expressing the USB transgene. Some of the immunolabeling in the
latter is due to antibody recognition of a truncated from of Smaug expressed
in the smg1 mutants (see E). Embryos are oriented with
their anterior pole facing leftwards. (D) Single confocal mid-section
showing Smaug immunolabeling in an embryo from a wild-type female expressing
the USB transgene. Average cortical pixel intensity in wild-type
embryos (red line, n=4) was subtracted from average cortical pixel
intensity in embryos from wild-type females expressing USB (blue
line, n=4). 100% designates the anterior pole and 0% represents the
posterior pole. (E) Western-blot showing Smaug protein expression in
embryos from wild type (wt), smg-mutant females and
smg-mutant females expressing the USB transgene. Embryos
were 0-3 hours old. Full-length Smaug (Smg) and a truncated form of the
protein (Smg*) expressed in smg1 mutants are
indicated. β-Tubulin (β-Tub) is a loading control.
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Fig. 6. Smaug protein gradient triggers graded cell cycle delays and
cellularization. (A,B) Embryos co-stained with a phospho-Tyrosine antibody
(grayscale and green) and TOTO3 (red), to visualize membranes and nuclei at
cellularization. (A) Nuclear density is uniform along the
anterior-posterior axis of wild-type interphase 14 embryos undergoing
cellularization. (B) An embryo expressing a Smaug gradient. The
anterior pole cellularizes at cell cycle 13 nuclear density (ANT inset), the
middle cellularizes at cycle-14 density (MID inset) and the posterior pole is
disorganized (POS inset). (C,D) Embryos labeled for mitotic
nuclei with anti-phospho-Histone-3 antibody (grayscale and green) and for DNA
with TOTO3 (red). Wild-type cycle 11 embryos divide synchronously along the
anterior-posterior axis (C). Embryos expressing Smaug in a gradient show cell
cycle delays at the anterior pole (D). In this example, the posterior is in
mitosis while the anterior is in late interphase or prophase (D).
(E,F). Time-lapse DIC microscopy of cellularization in wild-type
and USB embryos. (E) Wild-type embryos consistently cellularize
synchronously along the anterior-posterior axis (see Movie 1 in the
supplementary material). (F) USB embryos, by contrast, consistently initiate
cellularization at the anterior pole, and membrane invagination progresses in
a wave towards the posterior pole (see Movie 3 in the supplementary material).
Region of nuclear dropout is indicated by an asterisk. Embryos are orientated
with their anterior pole leftwards. High-magnification views at anterior
(ANT), middle (MID) and posterior (POS) regions are shown below each whole
embryo image. Arrows indicate the position of the celluarization front.
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Fig. 7. A Smaug gradient triggers graded transcription and maternal mRNA
destruction. (A-H) Zygotic expression of runt and
slam in wild-type and USB embryos. In wild-type controls,
both genes are expressed at low levels during cycle 13 (A,E) but are
significantly upregulated during interphase 14 (B,F). As cellularization is
initiated, USB embryos express slam (C) and runt (G) only at
the anterior pole, where Smaug expression is highest. (I-L). In later
embryos, slam expression is highest at the posterior pole and has
begun to decline at the anterior, whereas the striped pattern of runt
expression has extended to the posterior pole (D,H). In wild-type embryos,
maternal cyclin B mRNA is uniformly expressed during interphase 13
(I) and degraded throughout the embryo during interphase 14 (J). Only the pole
cells retain maternal cyclin B transcript during interphase 14 (J).
(I) In USB embryos, cyclin B mRNA is degraded in an
anterior-to-posterior gradient during interphase 13 (K,L). All transcripts
were detected by fluorescent whole-mount in situ hybridization, and embryos
where co-stained with TOTO3 (red) to visualize nuclear density. Embryos are
orientated with anterior towards the left. Insets show higher magnification
images of RNA (green) and DNA (red) in the anterior region of each embryo.
Scale bar: 100 µm.
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Fig. 8. Model for Smaug-dependent control of the MZT. We propose that
Smaug-dependent destruction of maternal mRNAs encoding transcriptional
repressors and cell cycle activators leads to coordinated activation of the
basal transcription machinery and the replication checkpoint. An initial wave
of transcription then produces proteins and miRNAs that feed back to enhance
maternal transcript destruction (e.g. mir-309) and activate additional genes,
thus completing the transition to zygotic control of embryogenesis. The
replication checkpoint coordinately couples the cell cycle to the N/C ratio
and thus determines the number of divisions that are completed before
cellularization.
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© The Company of Biologists Ltd 2009
