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PLoS One. 2012; 7(3): e33538.
Published online Mar 20, 2012. doi:  10.1371/journal.pone.0033538
PMCID: PMC3308990
Disruption of Murine mp29/Syf2/Ntc31 Gene Results in Embryonic Lethality with Aberrant Checkpoint Response
Chia-Hsin Chen,#1 Po-Chen Chu,#1 Liekyeow Lee,1 Huang-Wei Lien,2 Tse-Ling Lin,3 Chi-Chen Fan,4 Peter Chi,1,3 Chang-Jen Huang,1,3 and Mau-Sun Chang1,3*
1Institute of Biochemical Sciences, College of Life Science, National Taiwan University, Taipei, Taiwan
2Institute of Fisheries Science, College of Life Science, National Taiwan University, Taipei, Taiwan
3Institute of Biological Chemistry, Academia Sinica, Taipei, Taiwan
4Department of Physiology, Mackay Memorial Hospital, Taipei, Taiwan
Edward E. Schmidt, Editor
Montana State University, United States of America
#Contributed equally.
* E-mail: mschang/at/ntu.edu.tw
Conceived and designed the experiments: MSC . Performed the experiments: CHC PCC LL HWL TLL CCF . Analyzed the data: PC. Contributed reagents/materials/analysis tools: CJH. Wrote the paper: MSC.
Received December 19, 2011; Accepted February 10, 2012.
Human p29 is a putative component of spliceosomes, but its role in pre-mRNA is elusive. By siRNA knockdown and stable overexpression, we demonstrated that human p29 is involved in DNA damage response and Fanconi anemia pathway in cultured cells. In this study, we generated p29 knockout mice (mp29GT/GT) using the mp29 gene trap embryonic stem cells to study the role of mp29 in DNA damage response in vivo. Interruption of mp29 at both alleles resulted in embryonic lethality. Embryonic abnormality occurred as early as E6.5 in mp29GT/GT mice accompanied with decreased mRNA levels of α-tubulin and Chk1. The reduction of α-tubulin and Chk1 mRNAs is likely due to an impaired post-transcriptional event. An aberrant G2/M checkpoint was found in mp29 gene trap embryos when exposed to aphidicolin and UV light. This embryonic lethality was rescued by crossing with mp29 transgenic mice. Additionally, the knockdown of zfp29 in zebrafish resulted in embryonic death at 72 hours of development postfertilization (hpf). A lower level of acetylated α-tubulin was also observed in zfp29 morphants. Together, these results illustrate an indispensable role of mp29 in DNA checkpoint response during embryonic development.
Gene expression is regulated by a series of events taking place at both the transcriptional and post-transcriptional levels through mechanisms of pre-mRNA splicing, mRNA stability and mRNA transport. In eukaryotes, introns must be removed from precursor mRNA (pre-mRNA) by the spliceosome. U1, U2, U4, U5, and U6 small nuclear ribonucleoproteins (snRNPs) are the main elements of the spliceosome responsible for removing the majority of pre-mRNA introns. Moreover, each snRNP consists of one or two small nuclear RNAs (snRNAs) and many associated proteins, namely pre-mRNA processing proteins (Prp). Mutantions in Prp have been shown to be defective in removal of pre-mRNA introns [1].
Syf2/Ntc31, a putative homolog of human p29 in Saccharomyces cerevisiae, was independently identified as a synthetic lethal mutant accompanied with the absence of PRP17/CDC40 gene and a component of the Prp19p-associated complex [2], [3]. Although mutation in SYF2/NTC31 has no apparently aberrant cell cycle phenotype, lower levels of U5 and U6 snRNPs were pulled down with Syf1p/Syf3p/Isy1p in SYF2 deletion mutant [4]. Deletion of two non-essential splicing factors ISYL1 and SYF2 shows a reduced expression of α-tubulin at the restrictive temperature, which results in the G2/M cell cycle arrest [5]. This indicates that Syf2 and Isy1 are synergenically responsible for TUB1 and TUB3 pre-mRNA splicing in yeast. Clf1 is a conserved spliceosome assembly factor with tetratricopeptide repeats (TPR). Clf1 has been shown interact with Syf2 from the results of yeast two-hybrid analyses and protein-binding assays [6]. Mass spectrometry analyses of human spliceosomes reveal that human p29/syf2/Ntc31p associates with Prp19 and appears in the complex B/C of spliceosomes [1], [5], but the precise role of p29 in pre-mRNA splicing is unclear.
In addition to its putative involvement in pre-mRNA splicing, we have found that human p29 plays an important role in the regulation of DNA damage response (DDR) [7]. It is well known that cells will exploit DDR to maintain their genome integrity upon genotoxic stress. Formation of double strand breaks activates poly(ADP-ribose) polymerase 1 (PARP1), which recruits the Mre11-Rad50-Nbs1 (MRN)/ATM complex to the damaged sites. Subsequently, activation of ATM kinase leads to phosphorylation of downstream targets, such as Chk2 and p53. By contrast, DNA lesions induced by replication stress or UV irradiation result in the accumulation of RPA-coated ssDNA and loading of ATR-ATRIP and Rad9-Rad1-Hus1 (9-1-1) complex. Stimulation of ATR kinase by the 9-1-1 associated protein TopBP1 activates ATR signaling cascade, including downstream Chk1 phosphorylation [8]. We have reported that depletion of human p29 downregulated Chk1 phosphorylation upon UV irradiation and resulted in premature chromatin condensation which initiated apoptosis [7]. Analyses of U2OS cells with constitutive p29 expression revealed increased phosphorylation levels of Chk1 and Chk2. Moreover, the monoubiquitination of FANCD2 and FANCI complex was restored in Fanconi anemia complementation group G (FA-G) cells stably expressing p29 [9]. We further established mp29 transgenic mice under the control of mouse PGK1 promoter. The elevated expression of mp29 protein in mp29Tg/+ heterozygous mice was confirmed in the tissue extracts prepared from the brain, kidney, spleen, liver and testis by immunoblotting. Additionally, lower tumor incidence was found in mp29 transgenic mice after UV irradiation [9]. However, an mp29 deficient mouse model has not been established yet.
To investigate the function of mp29 in vivo, we generated mp29 deficient mice using a gene trap ES cell line. Molecular examinations of mp29GT/GT mutant embryos, a complementation test with mp29 transgenic mice, and morpholino (MO) knockdown of zfp29 in zebrafish indicate that mp29/syf2/Ntc31 plays a crucial role for the survival of embryos.
Generation of mp29 knockout mice
Mouse mp29 shares approximate 13% of amino acid identity with yeast Syf2 (Figure S1 for the first supporting information figure). The wild-type murine mp29 gene locates on chromosome 4 and contains 7 exons [10]. The location of a gene trap vector was inserted between exon 2 and 3 on mp29 gene (Fig. 1A). Chimeras capable of germ-line transmission were backcrossed to strain C57BL/6 mice to generate mp29 gene-trap heterozygous mice (mp29GT/+), which were in the 129Sv2/C57BL6 mixed background. Adult heterozygous mice were healthy and fertile. Male and female mp29GT/+ mice were intercrossed to produce mp29 gene-trap homozygous mice (mp29GT/GT). PCR analyses were used to determine the genotypes of the offsprings at age of 4 weeks (Fig. 1B). Out of 86 progeny analyzed, mp29+/+ and mp29GT/+ mice were approximately in a ratio of 1[ratio]2 and no significant phenotypic differences were found among these mice. Nevertheless, we did not detect any mice inherited with two interrupted alleles (Fig. 1C), indicating that a loss of function of mp29 might be embryonic lethal.
Figure 1
Figure 1
Interruption of mouse mp29 gene by a gene trap vector.
Abnormality of mp29GT/GT embryos
E3.5 blastocysts were collected and cultured individually in vitro. Genotyping of embryos was carried out using PCR analysis (Figure S2 for the second supporting information figure). We did not find any mp29GT/GT embryos after E11.5 (Table 1). Microscopic inspection of each embryo reveals no gross morphologic defects from E3.5 to E5.5 (Fig. 2A and Figure S2B for the second supporting information figure). In mp29+/+ blastocysts, normal trophoblast giant cells and inner cell mass could be observed at E6.5. However, mp29GT/GT blastocysts exhibited a shrink shape without hatching (Fig. 2A).
Table 1
Table 1
Analysis of embryos from intercrosses of mp29GT/+ mice.
Figure 2
Figure 2
Loss of mp29 resulted in aberrant embryonic development.
At E7.5, mp29GT/GT embryos did not undergo normal gastrulation, which led to the formation of embryonic ectoderm, mesoderm, and endoderm (Fig. 2B). Furthermore, mp29GT/GT embryos at E8.5. and E9.5 displayed a severely impaired embryonic development of head, trunk, and appendages. In contrast, mp29+/+ mp29GT/+ embryos at E8.5 had normal organogenesis (Fig. 2B). Western blot analysis showed the absence of mp29 protein in mp29GT/GT embryos at E7.5 (Fig. 2C), suggesting that the ablation of mp29 deteriorated the survival of mp29GT/GT embryos. A low level of mp29 appeared after a long exposure for immunoblotting or RT-PCR analyses (Fig. 2C and Fig. 3B), which was likely due to an incomplete interruption of inserted mp29 gene or a contamination of mother tissues.
Figure 3
Figure 3
Decreased α-tubulin and Chk1 expression in mp29GT/GT embryo.
Reduced α-tubulin and Chk1 expression in mp29GT/GT embryos
Previous studies show that double mutant isy1Δ and syf2Δ lead to a low level of α-tubulin expression in yeast and p29 affects Chk1 and Chk2 expression in human cells [3], [7]. Thus, we examined the expression of α-tubulin, Chk1 and Chk2 in mp29GT/GT embryos. As shown in Fig. 3A, the protein levels of α-tubulin, Chk1, and Chk2 were reduced in mp29GT/GT embryos at E7.5. RT-PCR revealed decreased mRNA levels of α-tubulin, Chk1, and Chk2 (Fig. 3B). Quantitative real-time PCR analysis showed lower levels of α-tubulin and Chk1 pre-mRNA and mRNA transcripts in mp29GT/GT embryos at E7.5 compared with wild-type and mp29GT/+ embryos (Fig. 3C), indicating that mp29 might be involved in transcriptional and post-transcriptional regulation of α-tubulin and Chk1. RNA immunoprecipitation showed that HA-mp29 preferentially pulled down pre-mRNAs of α-tubulin and Chk1 in NIH3T3 cells, but only a much smaller amounts of β-tubulin and Chk2 pre-mRNAs were pulled down (Figure S3 for the third supporting information figure), indicating that the decreased Chk2 expression in mp29GT/GT embryos might not be a direct effect of mp29 deficiency.
The isolation of mouse embryonic fibroblasts (MEFs) from mp29GT/GT embryos at E7.5 was unsuccessful, possibly due to its lack of viability. Alternatively, we silenced mp29 expression in mouse NIH3T3 embryonic fibroblasts using RNA interference strategy. Introduction of mp29 siRNA duplexes into NIH3T3 cells significantly reduced the mRNA and protein levels of α-tubulin and Chk1, but had a minimal effect on those of β-tubulin and Chk2 (Fig. 3 and Figure S3A for the third supporting information figure). Additionally, after transfection of an E1A alternative splicing reporter into NIH3T3 cells, mp29 depletion significantly decreased expression levels of 13S, 12S, and 10S transcripts with an elevated 9S transcript expression (Fig. 3D), suggesting that the mp29 might play a role in the post transcriptional control on its target genes both in mp29GT/GT embryos and mp29 silenced NIH3T3 cells.
Defective checkpoint in mp29GT/GT embryos
In accordance with our previous results [7], mouse Chk1 phosphorylation at S345 was reduced in mp29 knockdown NIH3T3 cells upon UV irradiation (Figure S3B for the third supporting information figure). To examine the effects of mp29 deficiency on DNA damage response in mp29GT/GT embryos, we collected E3.5 blastocysts from heterozygous intercross and cultured these embryos individually in the presence of aphidicolin to induce DNA replication stress, followed by nocodazole treatment for cell cycle arrest at the prophase. The immunostaining of anti-Histone H3 phosphorylated at Ser10, an M phase specific marker, showed that phosphohistone H3-positive cells were significantly increased in aphidicolin and nocodazole treated mp29GT/GT embryos (Fig. 4A). Similarly, phosphohistone H3-positive cells were increased in mp29GT/GT embryos and terminal deoxytransferase-mediated deoxyuridine nick end-labeling (TUNEL)-positive cells were detected in mp29GT/GT embryos at E3.0 after UV light exposure and nocodazole treatment (Fig. 4B). Additionally, mp29GT/GT embryos irradiated with UV light exhibited an increased level of γ-H2AX staining (Figure S4 for the fourth supporting information figure). Together, these results indicated an insufficient checkpoint capacity at G2/M to arrest cell cycle progression in mp29GT/GT embryos, which might be responsible for the genome instability and the restrictive viability upon replication stress and DNA damage.
Figure 4
Figure 4
Impaired G2/M checkpoint in mp29GT/GT embryos.
Complementation of mp29 expression with mp29 transgenic mice
To avert the possibility that mp29GT/GT abnormality resulted from a random integration by the gene trap vector, mp29GT/+mp29Tg/+ male littermates were generated by outcrossing mp29GT/+ mice in the 129Sv2/C57BL6 mixed background with mp29Tg/+ transgenic mice in the FVB genetic background. Inbreeding of mp29GT/+mp29Tg/+ male mice with mp29GT/+mp29+/+ female mice gave birth to mp29GT/GTmp29Tg/+ mice. Genotyping results revealed the presence of mp29 transgene in eight homozygous mp29 gene-trap mice among 76 offsprings. As anticipated, no embryonic lethality occurred in these mp29GT/GTmp29Tg/+ mice (Fig. 5A and 5B). The expression of mp29, α-tubulin, Chk1, and Chk2 were restored in mp29GT/GTmp29Tg/+ mice (Fig. 5C). Morphology of mp29GT/GTmp29Tg/+ mice is indistinguishable from mp29+/+mp29Tg/+ and mp29GT/+mp29Tg/+ mice. Furthermore, histological staining of liver and spleen tissues from mp29GT/GTmp29Tg/+ mice did not show significant differences from those of mp29+/+mp29Tg/+ and mp29GT/+mp29Tg/+ mice (Figure S5 for the fifth supporting information figure). Collectively, the molecular and morphological defects in mp29GT/GT mice could be rescued by mp29 transgene.
Figure 5
Figure 5
mp29 transgene complemented the deficiency of mp29.
Morpholino knockdown of zfp29 in zebrafish
Amino acid alignment showed that mouse mp29 shares nearly 80% sequence identify with zebrafish zfp29 and 12.3% sequence identity with yeast Syf2 (Figure S1 for the first supporting information figure). Since the amino acid sequences of p29 were highly conserved in vertebrates, we examined whether zfp29 deficiency would also result in an impaired embryogenesis. One hundred zebrafish embryos at 2–4 cells were injected with a zfp29 morpholino oligonucleotide, zfp29MO. The morphological results showed that more than 75% of the zfp29 morphants exhibited an abnormal development, including a small head, yolk extension, bent trunk, and crooked tail, at 24 hpf and died at 72 hpf (Fig. 6A). Acridine orange staining, a fluorescent dye to identify engulfed apoptotic cells, indicated a remarkable increase in apoptotic cells in zfp29MO-injected embryos. Since there were no suitable antibodies against Chk1 in zebrafish, we checked the expression level of acetylated α-tubulin, an early developmental marker for motor neurons. The distribution of acetylated α-tubulin was significantly reduced and less neurons/neurites appeared in zfp29 morphants compared with uninjected embryos (Fig. 6B). To further support these neuronal deformities, a wholemount in situ RNA hybridization against HuC, an early pan-neuronal marker in zebrafish [11], also displayed a significant loss of neuronal cells in the spinal cord in zfp29 morphants. Additionally, knockdown of zfp29 in the Fli transgenic line [12], which specifically expresses green fluorescence protein in blood vessels, also disturbed the blood vessel formation (Figure S6 for the sixth supporting information figure). Taken together, these results indicated that the abnormities of zfp29 knockdown affected the whole body development and were not restricted to specific tissues.
Figure 6
Figure 6
Effects of MO-mediated zfp29 knockdown in Zebrafish.
We have generated mp29 knockout mice from the mp29 gene-trap embryonic stem cell. Mice carrying a heterozygous insertion between exon 2 and exon 3 of mp29 gene were viable and their offsprings are able to inherit the mutated allele. However, embryos inherited with homozygous insertion in mp29 gene were not viable and mp29GT/GT embryos showed developmental defects at E6.5, partly due to an aberrant DNA damage checkpoint in cell cycle.
Mass spectrometry analysis identified several major components for pre-mRNA splicing, such as U5 snRNP, Prp 8, and hnRNPA2/U, in HA-mp29 immunoprecipitated complexes, suggesting an association of mp29 with pre-mRNA complex (Table S1 for the first supporting information Table). Homozygous inactivation of mp29/Syf2 in mice embryos and knockdown of mp29 in NIH-3T3 cells profoundly decrease the expression of α-tubulin and Chk1. In contrast, no significant effect was on β-tubulin and Chk2 (Fig. 3 and Figure S3 for the third supporting information figure). This result is contrary to the deletion of SYF2 from the previous study in Saccharomyces cerevisiae, which has no notable difference cell cycle progression or in splicing of U3 transcripts. Instead, a lower expression of α-tubulin was only found in double mutant isyl1Δ and syf2Δ cells [3], [4]. This conflicted phenomenon can be explained by the low similarity between mouse mp29 and yeast Syf2. There might be different regulatory mechanisms that prevail in these two species. This contention is also supported by the decreased expression of acetylated α-tubulin in zfp29 depleted zebrafish (Fig. 6B). However, knockdown of human p29 in HeLa and U2OS does not result in an alleviated α-tubulin expression [7], indicating that depletion of human p29 may not affect the post-transcriptional regulation of α-tubulin in human cancer cells.
Several DDR- and pre-mRNA splicing-related knockout mice have been investigated. For example, ATM knockout mice are viable, but display growth retardation, infertility, defects in T lymphocyte maturation, and extreme sensitivity to γ-irradiation [13]. Chk2-deficient mice exhibit radioresistance and defective p53-mediated transcription [14]. By contrast, the absence of main players in replication checkpoint results in severely developmental abnormalities. Aberrant cell cycle checkpoint and embryonic death as early as E3.5 are found in ATR and Chk1 deficient mice [15][17], implying that ATR and Chk1 are essential for the embryonic development and distinct from ATM and Chk2. Although major events associated with DNA damage and replication checkpoints are well defined, it is unclear whether there is a splicing checkpoint to prevent errors during pre-mRNA splicing process. Several components of splicing factors have been identified to participate in pre-mRNA splicing and DNA repair. For instance, SNEV (Prp19/Pso4) is a nuclear matrix protein involved in pre-mRNA splicing, ubiquitylation, and DNA repair. Mouse SNEV is indispensable for early mouse development and mutant SNEV results in preimplantation lethality at E3.5 [18]. The mammalian Pso4 complex, PSO4/PRP19/SNEV, CDC5L, PLRG1, and SPF27, is involved in both pre-mRNA splicing and DNA damage response [19]. Cdc5L interacts with ATR and is involved in the regulation of the ATR-mediated cell-cycle checkpoint in response to genotoxic agents [20]. Inactivation of PLRG1 in mice results in embryonic lethality at 1.5 days post-fertilization [21]. Disruption of murine mp29 gene resulted in the embryonic lethality, which is reminiscent of the phenotype of ATR, Chk1, SNEV, and PLRG1, leading to a conclusion that mp29/Syf2/Ntc31 may play substantial roles in DNA damage response by modulating transcriptional and post-transcriptional control of a certain set of target pre-mRNAs.
Animals
A gene trapped mouse E14 embryonic stem cell (PST25562-NR) with a 129Sv2 background was obtained from Mammalian Functional Genomics Center [22]. The E14 ES cell was injected into mouse strain C57BL/6 blastocysts to generate chimeric mice by Transgenic Core Facility at the National Taiwan University Hospital. C57BL/6 mice were purchased from BioLASCO Taiwan. The establishment of mp29 transgenic FVB mice has been described [9]. We would be willing to provide the mice models for the research purpose upon request.
Ethics statement
All animal studies were performed in compliance with the protocol #97060 of the Institutional Animal Use and Care Committee, National Taiwan University. All efforts were carried out to minimize suffering.
Generation of mp29 knockout mice
Two independent male chimeric mice with germ line transmission were back-crossed with female C57BL/6 mice to generate mp29 heterozygous F1 offsprings. Heterozygous male and female mice were bred to isolate wild-type (mp29+/+), heterozygous (mp29GT/+), and homozygous mutant (mp29GT/GT) mice.
Genotyping
Mouse tails (0.5 cm) were cut with scissors, ground to homogenize the tail tissues, and incubated in 20 µl of Proteinase K (10 mg/ml) at 60°C for 30 min. Tail DNAs were isolated using EasyPure Genomic DNA spin kit (Bioman, Taipei, Taiwan) for PCR. The following pairs of primers were used to examine the presence of inserting vector, U3NeoSV1. NSPF1: 5′-CATTACCGGGTGTACCTTAGGT-3′; NeoES 5′-AATCCATCTTGTTCAATCATGC-3′ and Ltr 5′-AGTTGCATCCGACTTGTG-3′; NSPR1 5′-GCATGCC TTTTGAATTATAGTCC-3′. NSPF1 and NSPR1 were used to amplify the untargeted mp29 allele with a product of 300 bp, which would be absent in mp29GT/GT mutants. PCR conditions were performed at 95°C for 3 min followed by 35 cycles of 95°C for 20 s, 57°C for 20 s, and 72°C for 30 s.
Blastocyst culture
Embryos at E3.5 were collected by flushing the uterus with PBS and cultured in HEPES-buffered M2 medium (Sigma-Aldrich) for 4 days until embryos hatched. Embryos were inspected daily and photographed to monitor their developments.
Western blotting
Protein extracts from mouse NIH3T3 cells, embryos, and adult tissues were solubilized in RIPA buffer (25 mM Tris-HCl pH 7.5, 150 mM NaCl, 1% NP-40, 1% sodium deoxycholate, 0.1% SDS, protease inhibitors) on ice for 30 min and sonicated for 5 min using a sonicator Misonix S-4000 (Farmingdale, NY). Rabbit anti-Chk1 and Chk2 antibodies were purchased from Cell Signaling (Beverly, MA). Mouse anti-α/β-tubulin and acetylated α-tubulin antibodies were from Sigma-Aldrich (St. Louis, MI). Mouse anti-GAPDH antibody was obtained from Santa Cruz Biotech (Santa Cruz, CA). Mouse anti-mp29 monoclonal antibody has been described [10].
RNA isolation and quantitative real time PCR
Total RNA was isolated using Trizol, treated with RNase-free DNase I (Promega), and transcribed into cDNA using Superscript III reverse transcriptase (Invitrogen). Real time quantitative PCR was performed using the Maxima SYBR Green kit (Fermentas, CA) on a ABI 7300 Sequence Detection System (PE Applied Biosystems) using a heat-activated TaqDNA polymerase (PE Applied Biosystems). The sequences of primers were listed below: for α-tubulin pre-mRNA (5′-TGAGCCAGCCAACCAGATG-3′ and 5′-TGGTCTTGATGGTGGCAATG-3′), for α-tubulin mRNA (5′-CCAGCCCCCCAGGTTTC-3′ and 5′-TGTCTACCATGAAGGCACAATCA -3′), for Chk1 pre-mRNA (5′-TATCCCCACCCCTCAGTTTTG-3′ and 5′-AGAGACACCTCCACCCGCT-3′), for Chk1 mRNA (5′-CTGGTTCAGGGCATCAGTTTTT-3′ and 5′-GGTAAGATTTGTCCGCATCCA-3′), for GAPDH (5′-TGACATCAAGAAGGTGGTGAAG-3′ and 5′-AGAGTGGGAGTTGCTGTTGAAG-3′). The relative transcript amount of the target gene, which was calculated using standard curves of serial RNA dilutions, was normalized to that of GAPDH of the same RNA.
siRNA transfection
An mp29 siRNA, 5′-CAGAGGAAAUUGACAGAA-3′, was incubated with RNAiMax lipofectamine (Invitrogen) at room temp for 20 min. Cells were washed with PBS and incubated in serum-free culture medium. The siRNA-RNAiMax complex was dropped onto cells and mixed gently by rocking the plate back and forth. Fetal bovine serum was added at 8 h post-transfection. Cell extracts were collected at 72 h post-transfection.
In vivo splicing assay
NIH3T3 cells were transfected with the E1A expression vector (pCEP4-E1A) as previously described [23] with minor modifications. Briefly, NIH3T3 cells were transfected with 20 nM of siRNA for 48 h and then co-transfected with E1A vector for another 24 h. Total RNA was isolated using Trizol reagent and treated with RQ-DNase I. RT-PCR was performed using primer P1 (5′-GGTCTTGCAGGCTCCGGTTCTGGC-3′) and P2 (5′-GCAAGCTTGAGTGCCAGCGAGTAG-3′). PCR products were fractionated on agarose gels and images were recorded. Quantitative results were carried out with three independent experiments.
Immunofluorescence
Embryos were fixed with 4% paraformaldehyde in PBS for 20 min and then permeabilized for 10 min at room temperature with PBS containing 0.3% Triton X-100. The aphidicolin or UV treated embryos were stained with DAPI and labeled with antibody specific to phosphohistone H3 at Ser10 (Cell Signaling). DNA fragmentation associated with apoptosis was detected with an in situ cell death detection kit (Roche). Permeabilized embryos were double stained with anti-phosphohistone H3 at Ser10 antibody and TUNEL reaction mixture for 60 min at 37°C. Fluorescein-labeled DNA was analyzed using a fluorescence microscope.
Complementation of mp29 deficiency with mp29 transgenic mice
mp29GT/+ mice were outcrossed with mp29Tg/+ mice to produce mp29GT/+mp29Tg/+ littermates. Inbreeding of mp29GT/+mp29Tg/+ male mice with mp29GT/+mp29+/+ female mice gave birth to mp29GT/GTmp29Tg/+ mice. Genotyping was performed as described above.
Morpholino injection
Respective morpholino oligonucleotides (MOs) were synthesized by Gene Tools (Philomath, OR, USA). The MO was dissolved in Danieau solution containing 0.5% phenol red and 3.2 ng per zebrafish embryo (Danio rerio) was injected into embryos at the two-cell stage. MO sequences are: zfmp29, 5′-TCGCTAGACGCCATGTTGCTTTTCG-3′. After 24 hpf, apoptotic cells were stained with acridine orange (Sigma-Aldrich, St. Louis, MO). Injected and uninjected embryos were fixed and immunostained with anti-acetylated α-tubulin antibody (Sigma-Aldrich).
Figure S1
Amino acid alignment of human p29 (AAG42073), mouse mp29 (NP_081058), zebrafish zfp29 (NP_001003437), and yeast Syf2 (NP_011645).
(TIF)
Figure S2
Genotyping and histological analyses of mp29 gene-trap embryos. (A) PCR analysis was conducted to determine the genotypes of embryos at E6.5. NSPF1/NeoES were used to detect the presence of gene trap vector and NSPF1/NSPR1 were used to identify homozygotes with two mp29 interrupted alleles. 18srRNA was used as a control. (B) Histological analysis of mp29 gene-trap embryos at E5.5.
(TIF)
Figure S3
RNA immunoprecipitation and siRNA depletion in NIH3T3 cells. (A) Mouse NIH3T3 cells were transfected with empty HA vector or HA-mp29 for 48 h and immunoprecipitated by anti-HA agarose. Total RNAs were transcribed for RT-PCR for indicated targets. (B) Mouse NIH3T3 cells were transfected with siRNAs for 72 h and total RNAs were transcribed for RT-PCR analysis. (C) NIH3T3 cells were transfected with siRNA duplexes for 72 h and whole cell extracts were prepared for Western blot analysis. (D) Mouse NIH3T3 cells were transfected with siRNA duplexes for 72 hours and then irradiated with UV light (50 J/m2). Cell extracts were harvested at 3 h post-UV treatment and Western blot was carried out using anti-Chk1 and Chk1 S345 antibodies. Note that a decrease of Chk1 phosphorylation at S345 in mp29 depleted cells. Hsp90 was used as a loading control.
(TIF)
Figure S4
Detection of γH2AX in mp29 gene-trap embryos. mp29+/+, mp29GT/+, and mp29GT/GT blastocysts at E3.5 were irradiated with UV light (50 J/m2), and then immunostained with anti-γH2AX antibody. The genotypes of each embryo were determined by PCR. Images were obtained using Leica DM6000B microscope.
(TIF)
Figure S5
Macro-inspection of mp29 transgene complement mice. (A) mp29GT/+ mice were outcrossed with mp29Tg/+ mice to generate mp29GT/+mp29Tg/+ littermates. Inbreeding of mp29GT/+mp29Tg/+ with mp29GT/+mp29+/+ mice gave birth to mp29GT/GTmp29Tg/+ mice. Morphology of mp29GT/+mp29Tg/+ inbreeding mice. (B) Hematoxylin–eosin staining of the liver and spleen tissues isolated from mp29+/+mp29Tg/+, mp29GT/+mp29Tg/+, and mp29GT/GTmp29Tg/+ mice.
(TIF)
Figure S6
Expression of HuC and blood vessel formation in zfp29 knockdown morphants. (A) Zebrafish embryos at 2-cell stage were uninjected or injected with zfp29 MO and then probed with DIG-labeled HuC probe for in situ hybridization at 24 hpf. (B) Two-cell embryos of Fli transgenic line were injected with control and zfp29 MO and then fixed for detection of green fluorescence protein expression.
(TIF)
Table S1
List of mp29 associated proteins identified by Mass spectrometry analysis.
(DOCX)
Acknowledgments
We are grateful to Dr. Geen-Dong Chang for critical reading and suggestions for this manuscript. We are also indebted to Drs. Soo-Chen Cheng and Woan-Yuh Tarn for helpful discussions and the E1A splicing factor from Dr. WY Tarn. We thank the technical services provided by the Transgenic Mouse Model Core Facility of the National Research Program for Genomic Medicine, NSC, and the assistance from Dr. Sheng-Wei Lin at IBC, Academia Sinica.
Footnotes
Competing Interests: The authors have declared that no competing interests exist.
Funding: This work was supported by grants from National Science Council (NSC 100-2311-B-002-013) and National Taiwan University (10R80837) to MSC. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
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