The Drosophila modulatory calcineurin-interacting protein (MCIP) sarah (sra) is essential for meiotic progression in oocytes. Activation of mature oocytes initiates development by releasing the prior arrest of female meiosis, degrading certain maternal mRNAs while initiating the translation of others, and modifying egg coverings. In vertebrates and marine invertebrates, the fertilizing sperm triggers activation events through a rise in free calcium within the egg. In insects, egg activation occurs independently of sperm and is instead triggered by passage of the egg through the female reproductive tract; it is unknown whether calcium signaling is involved. MCIPs [also termed regulators of calcineurin (RCNs), calcipressins, or DSCR1 (Down syndrome critical region 1)] are highly conserved regulators of calcineurin, a Ca2+/calmodulin-dependent protein phosphatase 1 and 2. Although overexpression experiments in several organisms have revealed that MCIPs inhibit calcineurin activity, their in vivo functions remain unclear. Eggs from sra null mothers are arrested at anaphase of meiosis I. This phenotype was due to loss of function of sra specifically in the female germline. Sra is physically associated with the catalytic subunit of calcineurin, and its overexpression suppresses the phenotypes caused by constitutively activated calcineurin, such as rough eye or loss of wing veins. Hyperactivation of calcineurin signaling in the germline cells resulted in a meiotic-arrestphenotype, which can also be suppressed by overexpression of Sra. All these results support the hypothesis that Sra regulates female meiosis by controlling calcineurin activity in the germline. This is the first unambiguous demonstration that the regulation of calcineurin signaling by MCIPs plays a critical role in a defined biological process (Takeo, 2006; Horner, 2006).

sarah mutation disrupts several aspects of egg activation in Drosophila. Eggs laid by sarah mutant females arrest in anaphase of meiosis I and fail to fully polyadenylate and translate bicoid mRNA. Furthermore, sarah mutant eggs show elevated cyclin B levels, indicating a failure to inactivate M-phase promoting factor (MPF). Taken together, these results demonstrate that calcium signaling is involved in Drosophila egg activation and suggest a molecular mechanism for the sarah phenotype. The conversion of the sperm nucleus into a functional male pronucleus is compromised in sarah mutant eggs, indicating that the Drosophila egg's competence to support male pronuclear maturation is acquired during activation. Despite its independence from a sperm trigger, egg activation in Drosophila involves calcium-mediated pathways that are likely to be analogous to those in other animals. It is intriguing that among these downstream events is the acquisition of the egg's competence to remodel the sperm nucleus into the male pronucleus (Horner, 2006).

To explore the in vivo function of the Drosophila MCIP Sra, a null mutation in this locus was created by gene targeting. Homozygotes of the null allele sra^KO are semilethal during larval or pupal stages. In addition, sra^KO females were sterile, and their ovulation is abnormal (Ejima, 2004). These phenotypes were rescued by either sarah transgenes. Taken together, these results unambiguously demonstrate that sra is responsible for the phenotypes associated with sra^KO, which include developmental defects in both sexes and ovulation and sterility in females (Takeo, 2006).

There is no apparent morphological abnormality in ovarian development in sra^KO females, but eggs from sra^KO mothers failed to hatch. Wild-type eggs at 2 hr after deposition already have completed meiosis and undergo synchronous mitotic nuclear division. In contrast, eggs—hereafter referred to as sra eggs—from sra^KO mothers had a localized DAPI-stained signal in the cortical region near the anterior pole, indicating that sra eggs are arrested during meiosis. To analyze this phenotype in detail, the pattern of chromosome segregation and the spindle shape of sra eggs were examined. Spindle microtubules were visualized with tubulin antibody staining. In wild-type females, mature oocytes are arrested at metaphase of meiosis I, during which the chromosomes are seen as a large mass of chromatin. After the release of meiotic arrest during ovulation, individual chromosome arms become visible and migrate toward the poles; the chromosomes subsequently undergo meiosis II, after which nuclear fusion and the mitotic divisions of the zygote take place. In sra eggs, the meiotic chromosomes were seen in between the metaphase plate and the poles. It was confirmed that the oocytes taken from sra mutants including sra^GS3080 and sra^GS3168 are arrested at metaphase I as in the wild-type. Therefore, sra eggs are arrested at anaphase I shortly after the meiotic resumption from the metaphase I arrest (Takeo, 2006).

To determine whether the meiotic-arrest phenotype of sra eggs is caused by loss of function in the germline or somatic cells of sra mothers, mutant germline clones were generated by the flippase-dominant female sterile (FLP-DFS) technique. All eggs laid by wild-type females completed meiotic divisions, whereas most eggs (98%) from sra mothers arrested at anaphase of meiosis I. sra germline clones were also arrested at anaphase I, reproducing the phenotype of sra^KO. A few sra eggs, including germline clones, were arrested at meiosis II. In these eggs, the two spindles were perpendicular to each other, rather than in tandem as in the wild-type. These results demonstrate that the meiotic defects in sra eggs are specifically attributable to the loss of function of sra in the female germline. Consistent with this conclusion, sra is highly expressed in the female germline during oogenesis (Ejima, 2004) and in early embryos. Furthermore, the meiotic-arrest phenotype caused by sra mutations was almost fully rescued by nos-GAL4/UASp-sra transgenes. These results establish that sra is required in the germline for meiotic progression in Drosophila females (Takeo, 2006).

Sra is a Drosophila member of the modulatory calcineurin-interacting protein (MCIP) family of proteins, which are known to function as endogenous regulators of calcineurin (Gorlach, 2000; Kingsbury, 2000; Lee, 2003; Fuentes, 2000). Calcineurin consists of two subunits, CnA and CnB. The Drosophila genome contains three genes encoding CnA subunits (CanA1, Pp2B-14D, and CanA-14F) and two genes encoding CnB subunits (CanB and CanB2). The functions of calcineurin have been poorly analyzed in Drosophila. It is hypothesized that sra functions as an endogenous regulator of calcineurin in Drosophila. Analyses of the expression pattern of Drosophila calcineurin genes by RT-PCR revealed that all three CnA and both CnB genes were expressed in larvae and adult females, but among these, only Pp2B-14D, CanA-14F, and CanB2 are expressed in early embryos and ovaries. Therefore, these three calcineurin subunits are candidates for interacting with Sra in the female germline (Takeo, 2006).

A constitutively active form of calcineurin can be created by truncating the C-terminal part of CnA (Sullivan, 2002; Gajewski, 2003). Misexpression of the active form of Pp2B-14D (Pp2B-14D^act) causes morphological abnormalities in eyes and wings (Sullivan, 2002). To determine the effects of sra on calcineurin signaling, whether activated calcineurin-dependent phenotypes can be modified by coexpression of sra was tested. Overexpression of sra alone in developing eyes by using GMR-GAL4 did not induce any phenotypic change. Flies misexpressing Pp2B-14D^act showed a mild rough-eye phenotype, which was completely suppressed by coexpression of sra. Similarly, misexpression of Pp2B-14D^act in the posterior compartment of developing imaginal discs by using en-GAL4 resulted in loss of wing veins and reduction of wing size. These wing phenotypes were also completely suppressed by coexpression of sra, whereas overexpression of sra alone had no effect on wing morphology. Furthermore, overexpression of sra rescued the lethality induced by the muscle-specific expression of Pp2B-14D^act by using 24B-GAL4. All these results clearly show that sra has an inhibitory effect on calcineurin signaling (Takeo, 2006).

If Sra acts as an inhibitor of calcineurin in vivo, it was speculated that calcineurin signaling is hyperactivated in sra mutants; that is, hyperactivation of calcineurin signaling might also affect the meiotic phenotype as in sra mutants. It was found that females carrying nos-GAL4 and UASp-Pp2B-14D^act had fully developed ovaries, but were sterile or semisterile, depending on the transgenic lines. The sterility or semisterility caused by nos>Pp2B-14D^act was effectively rescued by co-overexpression of sra, demonstrating that sra counteracts activated calcineurin (Takeo, 2006).

To characterize the meiotic phenotype caused by Pp2B-14D^act, eggs were stained from semisterile females expressing nos>Pp2B-14D^act (Ejima, 2004) with DAPI and tubulin antibody to visualize chromosomes and spindles, respectively. A total of 63 eggs were examined. Of these, 10% (6/63) developed normally, whereas 14% (9/63) had neither DAPI signaling nor tubulin antibody staining. The remaining 76% showed complex abnormalities that could be classified into three types: (1) dispersed chromatins with no obvious spindle (33%); (2) apparently normal chromosomes with an abnormal spindle (38%), and (3) a mass of chromatin with an apparently normal spindle (5%). Also the nuclei of mature oocytes taken from nos>Pp2B-14D^act (Ejima, 2004) females were observed to see whether meiotic arrest at metaphase I is normal. It was found that the majority had abnormal nuclei containing dispersed chromatins, and that the remaining were arrested at metaphase I or anaphase I. These results suggest that calcineurin signaling was activated to a greater extent in the germline of females constructed in this way than in sra mutants. Taken together, these results demonstrate that the regulation of calcineurin signaling is critical for female meiosis, and its regulator Sra/MCIP is essential for meiotic progression at the time of egg activation in the Drosophila female (Takeo, 2006).

In vertebrates whose meiotic arrest occurs at metaphase II, arrest is released at the time of fertilization. The mechanisms of meiotic arrest and resumption have been extensively studied in mice and frogs, and several key components have been identified, including Cdc2/Cyclin B (MPF) and MAP kinase. In addition, the so-called “Ca²⁺ transient” mediated by IP₃ signaling has been linked to egg activation; this transient promotes completion of meiosis, ion-channel opening, and cortical granule exocytosis. Recent studies have revealed that Ca²⁺/calmoduin-dependent protein kinase II (CaMKII) is physiologically activated in mouse oocytes in response to fertilizing sperm. CaMKII is implicated in the regulation of the timing of re-entry into mitosis through the phosphorylation of Cdc25C, a phosphatase mediating G1/M transition by dephosphorylating MPF in Xenopus. More recently, CaMKII was shown to phosphorylate an anaphase-promoting complex/cyclosome (APC/C) inhibitor, Emi1-related protein (Erp1), resulting in its degradation and thereby releasing the brakes on the cell cycle from metaphase II in Xenopus eggs (Takeo, 2006).

Less is known about the mechanism of egg activation in Drosophila. Genetic screens for female-sterile mutations have identified several genes involved in female meiosis. For example, twine, a homolog of Drosophila cdc25, is required for arrest at metaphase I in mature oocytes. cortex (cort) and grauzone (grau) mutant eggs exhibit meiotic arrest at meiosis II with defects in cytoplasmic polyadenylation and translation of maternal bicoid mRNAs. cort encodes an APC/C activator protein Cdc20, suggesting that APC/C-Cdc20^Cort-mediated inactivation of MPF is required for the translational control of poly(A)-dependent maternal mRNA. grau encodes a member of the C2H2-type zinc-finger protein family and activates transcription of cort to induce the completion of female meiosis. In addition, a recent study reported that a small cell-cycle regulator, Cks30A, plays an essential role in meiotic progression by associating with Cdk1 (Cdc2)/cyclin complexes and mediating Cyclin A degradation in the female germline. Therefore, cell-cycle regulators involved in meiotic progression are likely to be conserved between vertebrates and Drosophila (Takeo, 2006).

The involvement of calcineurin signaling in female meiosis has not previously been described in any organism. These studies on sra are the first to demonstrate that regulation of a Ca²⁺-dependent phosphatase is critical for the progression of female meiosis. Analyses of mutations in calcineurin genes and identification of the substrates in germline cells should facilitate further understanding of the role of calcineurin signaling in female meiosis (Takeo, 2006).

GENE STRUCTURE

cDNA clone length - 1929 bp

Bases in 5' UTR - 372

Exons - 2

Bases in 3' UTR - 678

PROTEIN STRUCTURE

Amino Acids - 292

Structural Domains

The sra gene encodes a protein consisting of 292 amino acids with sequence similarity to human genes Down syndrome critical region 1 (DSCR1), DSCR1-like1 (DSCR1L1), and DSCR1-like2 (DSCR1L2; Strippoli, 2000). It has a cadherin signature (amino acid residues 73-102) and an RNA recognition motif (118-188). Amino acid identities of Sra with the DSCR1 family proteins were 27% (80/297), 40% (79/197), and 36% (88/243) for DSCR1, DSCR1L1, and DSCR1L2, respectively. The sra locus consists of two exons interrupted by an 8731-base-long intron (Ejima, 2004).

date revised: 6 February 2007

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