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1 June 2009 CABS1 Is a Novel Calcium-Binding Protein Specifically Expressed in Elongate Spermatids of Mice
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Single intraperitoneal injection of busulfan at 20 mg/kg body weight to mature male mice induced the deletion of the spermatogenic cells, followed by the restoration of the spermatogenesis by the surviving undifferentiated spermatogonia. The changes of the protein contents in testis during these processes were analyzed by two-dimensional gel electrophoresis in order to identify the proteins expressed at the specific stages of spermatogenesis. An acidic protein that disappeared and recovered in the same time course as spermatids after the busulfan treatment was identified as CABS1 by mass spectrometry. It was found that CABS1 was specifically expressed in the elongate spermatids at steps 13 to 16 in stages I to VIII of the seminiferous epithelium cycle of the mouse, and then it localized to the principal piece of flagellum of the mature sperm in the cauda epididymis. We have found for the first time that CABS1 is a calcium-binding protein that binds calcium during the maturation in the epididymis.


Mammalian spermatogenesis is accomplished by the orderly series of differentiation steps. First, spermatogonia undergo multiplication by mitosis, leading to differentiation into spermatocytes. The spermatocytes then reduce the chromosomal number by meiosis, changing into haploid spermatids. The round spermatids finally differentiate into spermatozoa through the processes known as spermiogenesis. These steps are known to be regulated by the microenvironment surrounding the germ cells as well as by the stage-specific gene expression by the germ cells themselves. Although a number of genes and proteins have been identified in relationship to the specific stages of spermatogenesis, the molecular mechanisms involved in spermatogenesis remain largely unknown [18]. This is partly because of the lack of appropriate in vivo or in vitro model systems to analyze selectively the transcripts and/or proteins with specific localization in testis and the specific timing of expression during spermatogenesis.

In order to analyze the spermatogonial stem cell function, transplantation of germ cells into a host testis depleted of spermatogenic germ cells by treatment with busulfan has recently been employed [913]. Busulfan has been used as an antineoplastic through its alkylating property to inhibit DNA replication [14]. So, at adequate concentrations busulfan selectively attacks the dividing spermatogonia and spermatocytes, resulting in the depletion of the spermatogenic germ cells from testis without influencing the abilities of the testicular somatic cells to support spermatogenesis. Under such conditions, the busulfan-induced depletion of spermatogenic germ cells can be restored by surviving spermatogonial stem cells [12, 1517].

In the present paper, spermatogenesis was temporarily ceased by a single intraperitoneal injection of busulfan to the mature male mice, and then we investigated the first cycle of recovered spermatogenesis in order to identify the proteins expressed at the specific stages of spermatogenesis. Among those proteins, here we focused on an acidic protein, NYD-SP26, which had been reported as a gene highly expressed in human testis with unknown function [18]. We have found that NYD-SP26 is a novel member of the calcium-binding proteins in spermatozoa that is specifically expressed in the elongate spermatids and then localized into the principal piece of flagella of matured spermatozoa. Therefore, we have named this protein calcium-binding protein, sperm-specific 1—CABS1, which has been approved by the Mouse Genomic Nomenclature Committee and the HUGO Gene Nomenclature Committee.


Animals and Histology

Animal experiments were carried out in a humane manner after approval was received from the Institutional Animal Experiment Committee of the University of Tsukuba. IV-CS male mice (6 wk old) purchased from the Institute for Animal Reproduction (Kasumigaura-shi, Japan) received a single intraperitoneal injection of busulfan (20 mg/kg body weight; Sigma) dissolved in 50% dimethyl sulfoxide. Freshly dissected testes were fixed in Bouin fixing fluid, processed in paraffin, sectioned at 4 μm, and stained by hematoxylin and eosin.

Protein Extraction and Two-Dimensional Gel Electrophoresis

Testes were homogenized by Polytron (Kinematica AG) in 20 mM Tris-HCl, pH 7.4, containing 4% CHAPS and 20 μl/ml protease inhibitor cocktail (Sigma) and were incubated on ice for 60 min with periodic vortexing. The homogenate was centrifuged at 105 000 × g for 1 h at 4°C. The resulting supernatant was stored at −20°C until use.

A total of 450 μg of extracted proteins were separated on the pH 3–10, 7-cm immobilized pH gradient (IPG) strip (Bio-Rad) using a Protean IEF Cell according to the manufacturer's instructions (Bio-Rad). After isoelectric focusing, the IPG strip was successively equilibrated in the equilibration buffer (6 M urea, 2% SDS, 20% glycerol, and 375 mM Tris-HCl, pH 8.8) containing 130 mM dithiothreitol or 135 mM iodoacetamide each for 10 min at room temperature. The IPG strip was laid on the SDS-polyacrylamide 10% or 15% gel and electrophoresed with a MiniProtean II (ATTO Technology) at 200 V. Gels were stained overnight with Rapid Stain CBB kit (Nacalai Tesque, Kyoto, Japan) and then destained with 30% methanol and 10% acetic acid until a clear background was achieved. For image analysis, the stained two-dimensional gel electrophoresis (2-DE) gels were scanned with a GS-710 densitometer (Bio-Rad) and analyzed with the software PDQuest Version 6.2 (Bio-Rad).

Protein Identification by Mass Spectrometry

The spots of interest were excised from 2-DE gel, destained with 50% (v/v) acetonitrile and 2.5 mM Tris-HCl, pH 9.0, and dried in a vacuum centrifuge. The gel pieces were covered with 50 μl of 2.5 mM Tris-HCl, pH 9.0, containing 0.04 mg/ml lysyl endopeptidase (Wako, Osaka, Japan) and then rehydrated at 4°C for 40 min. The supernatant was then replaced by 100 ml of 2.5 mM Tris-HCl, pH 9.0, and the gel pieces were incubated overnight at 37°C.

The digested peptides were loaded onto C18 Zip Tips (Millipore, Framingham, MA) for desalting. Matrix-assisted laser desorption/ionization-time of flight (MALDI-TOF) mass spectra were acquired using a PerSeptive Biosystems Voyager Elite-DE (Framingham, MA).

For protein identification, monoisotopic masses of digested peptides observed in the MALDI-mass spectrometry spectra were used to query NCBInr and SWISS-PROT sequence databases using Mascot ( search programs.

RT-PCR Analysis

Total RNA was isolated from testes with ISOGEN (Nippon Gene, Tokyo, Japan) and subjected to RT-PCR. First-strand cDNA reverse transcribed using an oligo(dT) primer was further amplified by PCR. Oligonucleotide primers used in this study were 5′-CTCTGGCACACTAGAGGACA-3′ and 5′-GAGGTCACTGAAGGAAGCTC-3′ (nucleotides 530–549 and 1129–1110 in Supplemental Fig. S1 [available online at], respectively). Denaturation was for 30 sec at 94°C, annealing for 30 sec at 60°C, and synthesis for 2 min at 72°C.

Sequence Analysis of Cabs1 mRNA by RACE Methods

The nucleotide sequence of Cabs1 mRNA was determined by RACE methods using a 5′-Full RACE core set and 3′-Full RACE core set (Takara, Shiga, Japan) according to the manufacturer's instructions. Briefly, first-strand cDNA of Cabs1 was synthesized by reverse transcription from the mouse testis total RNA using 5′-end phosphorylated RT primer (nucleotides 549–536 in Supplemental Fig. S1). After digestion of RNA by RNase H, concatemers of single-stranded cDNA were formed by T4 RNA ligase. An unknown 5′-end region was amplified using inverse PCR (5′-RACE), and then its product was cloned into pGEM-T vector (Promega Corp.) for sequencing. For 3′-RACE, first-strand cDNAs were synthesized by RT of the mouse testis total RNA using Oligo dT-3sites Adaptor Primer contained in the 3′-Full RACE core set. Polymerase chain reaction was performed with a Cabs1-specific primer (nucleotides 1018–1057 in Supplemental Fig. S1) and the 3site Adaptor Primer, whose product was then cloned into the pGEM-T vector and sequenced.

Northern Blot Analysis

Total RNA prepared from various mouse tissues (10 μg each) was electrophoresed and transferred to the nylon membranes (Hybond-N+; Amersham). The RNA blots were hybridized with 600 bases of cRNA labeled with digoxygenin (Boehringer-Mannheim Biochemica). The RT-PCR product obtained as mentioned above was ligated into pCR II Vector (TA Cloning Kit Dual Promoter; Invitrogen). After linearization with BamHI or EcoRV, sense and antisense cRNA probes were synthesized by in vitro transcription with T7 or SP6 RNA polymerase (DIG RNA Labeling Kit; Roche Applied Science). The location of the cRNA probe in the Cabs1 mRNA is shown in Supplemental Fig. S1.

In Situ Hybridization

Fresh mouse testis was frozen quickly in liquid nitrogen, embedded in CMC compound (FINETEC), and then sectioned at 4 μm by Cryostat (Leica). The sections were fixed with 4% paraformaldehyde and then treated with 1 μg/ml proteinase K. After postfixation with 4% paraformaldehyde, the sections were washed with PBS containing 0.2% Tween-20 and hybridized with 1 μg/ml DIG-labeled cRNA probe dissolved in 50% formamide, 5× saline-sodium citrate (SSC), 1% SDS, 50 μg/ml heparin, and 50 μg/ml yeast RNA at 65°C overnight in a moist chamber equilibrated with 50% formamide and 2× SSC, pH 4.5. The sections were successively washed with 50% formamide; 5× SSC, pH 4.5; and 1% SDS at 65°C for 30 min and three times with 50% formamide and 2× SSC, pH 4.5, at 65°C for 30 min each. The sections then were washed three times with 25 mM Tris-HCl, pH 7.4, containing 0.8% NaCl, 0.002% KCl, and 0.1% Tween-20 (TBST) at room temperature for 5 min each. After treatment with 0.5% blocking reagent (Roche Applied Science) in TBST at room temperature for 1 h, the sections were incubated with alkaline phosphatase-conjugated anti-DIG antibody (Roche Applied Science) at 4°C overnight. The colorization was performed using BM purple AP substrate according to the manufacturer's instructions (Roche Applied Science).

Expression and Purification of the Recombinant Proteins for Antigen Production and for Analysis of Calcium-Binding Activity

Two recombinant proteins were prepared for antigen production and for analysis of calcium-binding activity. The Cabs1 cDNA fragments were synthesized by RT-PCR using testis total RNAs as template, and each was ligated into BamHI and EcoRI sites of the bacterial expression vector, either pGEX-2T (for antigen production) or pGEX-6P-2 (for the calcium-binding assay), which was transformed into Escherichia coli DH5α. After the purification of the recombinant GST-CABS1 fusion proteins, CABS1 protein fragments were cut out by thrombin or PreScisson Protease (Amersham Pharmacia Biotech) and purified using Glutathion Sepharose 4B (GE Healthcare) according to the manufacturer's instruction. The location of both recombinant proteins in CABS1 protein is indicated in Supplemental Fig. S1.

Production of Rabbit Antisera Against CABS1 and Western Blot Analysis

Rabbit antisera against the CABS1 protein fragment were produced by subcutaneous injection of 250 μg of purified antigen with Freund complete adjuvant (Sigma). Three additional booster injections of 125 μg of purified antigen with Freund incomplete adjuvant (Sigma) were followed at intervals of 2 wk.

The mouse testis proteins were separated by 2-DE and electroblotted to polyvinylidene fluoride (PVDF) membranes under semidry conditions. Membranes were treated with the antisera against CABS1, followed by peroxidase-conjugated anti-rabbit IgG secondary antibody (Sigma). Signals were detected by incubating the membranes with 0.06% 4-chloro-1α-naphtol and 0.01% H2O2 in 50 mM Tris-HCl, pH 7.4.

Immunohistochemical Analysis of Mouse Testis

Mouse testes were fixed by soaking in Bouin fixing fluid at room temperature for 24 h, and they then were dehydrated and embedded in paraffin. The block was sectioned at a thickness of 4 μm and mounted on slides. After deparaffinization, the sections were soaked in 0.1 M sodium citrate buffer at 37°C and washed with distilled water.

Immunohistochemical analysis was carried out by an avidin-biotin complex method using a Vectastain ABC Kit (Vector Laboratories Inc.) according to Noguchi et al. [19]. Specificity control for the immunohistochemical reaction was carried out on adjacent sections, which were incubated with the neutralized antisera instead of the anti-CABS1 antisera. Anti-CABS1 antiserum was neutralized by incubation with the purified antigen (1 mg/ml) at room temperature for 30 min. Counterstaining of the sections was done by hematoxylin and eosin.

Immunocytochemical Analysis of Mouse Sperm

The mature sperm squeezed out from the mouse cauda epididymis were washed with PBS and suspended to a final concentration of 4 × 106 cells/ml in PBS. Sperm suspension was placed on the MAS-coated slide (Matsunami Glass Ind. Ltd., Osaka, Japan) and dried at 50°C. After fixation with 4% paraformaldehyde in PBS on ice for 30 min, sperm were washed with PBS three times and blocked with 5% skim milk in PBS (blocking buffer) at room temperature for 30 min. Sperm were then exposed to the anti-CABS1 serum diluted with blocking buffer at 37°C for 1 h, followed by washing with PBS three times. Sperm were incubated with the fluorescein isothiocyanate-conjugated anti-rabbit IgG dissolved in blocking buffer at room temperature for 30 min. After washing with PBS, sperm were observed under a microscope. Specificity control was done as mentioned above.

Analysis of Calcium-Binding Activities

The calcium-binding proteins in the testicular protein extracts were detected by two methods. First, calcium-binding proteins were stained with Stains-all (1-ethyl-2-{3-(1-ethyl-naphtol [1,2-d] thiazoline-2-ylidine)-2-methylpropenyl}-naphtho [1,2-d] thiazolium bromide) in 2-DE gel according to the method of Campbell et al. [20]. Briefly, 2-DE gel was fixed with 25% isopropanol overnight and washed extensively with the same medium. Then, the gel was stained with 0.0025% Stains-all, 25% isopropanol, 7.5% formamide, and 30 mM Tris, pH 8.8, for 48 h in the dark. The calcium-binding proteins were stained in blue, whereas most other proteins were stained in red or pink.

Second, the calcium-binding proteins were stained with ruthenium red [21]. The PVDF transfers of testis proteins separated by 2-DE were incubated with or without 50 mM CaCl2 in 60 mM KCl, 5 mM MgCl2, and 10 mM Tris-HCl, pH 7.5 (buffer A) at 20°C for 30 min. The membranes were washed twice with buffer A for 10 min and then were stained with 25 mg/l ruthenium red in buffer A.

The calcium-binding activity was studied using a recombinant CABS1 protein, which covered the full length of the deduced CABS1 sequence except the N-terminal five amino acids, as shown in Supplemental Fig. S1. The purified recombinant CABS1 was incubated with 5 μM Stains-all in 30% (v/v) ethylene glycol, 2 mM MOPS-KOH, pH 7.2, in the dark for 30 min, and then the absorption spectra were obtained with a spectrophotometer as described by Caday and Steiner [22].


Effects of a Low Dose of Busulfan on Mouse Spermatogenesis

In order to determine the proteins expressed at the specific stages of spermatogenesis, busulfan was used to deplete the adult mouse testis of spermatogenic germ cells, followed by the recovery of spermatogenesis by the surviving spermatogonia. The effects of a single peritoneal injection of 10∼40 mg/kg busulfan on the mouse testis were determined. It was found that the least amount of busulfan that induces both the complete deletion of spermatogenic germ cells and the ensuing recovery of spermatogenesis was 20 mg/kg (Fig. 1a). As shown in Figure 1c, 32 days after the injection of 20 mg/kg busulfan, only undifferentiated spermatogonia were detected in the seminiferous tubules in addition to Sertoli cells. Reproliferation of the surviving germ cells was first observed 41 days after the injection (Fig. 1d). The first cycle of the resumed spermatogenesis proceeded synchronously in almost all seminiferous tubules. Spermatids appeared 7 wk after the busulfan treatment, and the spermiation occurred in the 11th wk (Fig. 1e).

Analysis of Proteins in the Busulfan-Treated Testis by 2-DE and TOF-MS

Proteins were extracted from the testes 32, 41, 56, and 77 days after the busulfan treatment and were separated by 2-DE. As shown in Figure 2 and Table 1 [2336], the testicular proteins identified by TOF-MS were categorized into three groups according to the pattern of the changes in the contents and using actin (spot no. 3) as an unchanged control: unchanged (I), temporarily increased (II), and temporarily decreased (III) proteins. Most of the proteins in group I had been known to be ubiquitously present in the testis. Because actin has been used generally as an internal control for the comparative experiments of testicular mRNAs and proteins [3739], the levels of actin remained constant throughout the processes examined in this study (Fig. 3f). All of the identified proteins that had already been reported to be localized either in the Sertoli cells or Leydig cells were shown to belong to group II. The proteins known to be present in the differentiated spermatogenic cells belonged to group III. The proteins specifically expressed in the undifferentiated spermatogonia were shown to be contained in group I or II.

In this study, we newly identified two proteins whose localization and function in the mouse testis had not been reported (Table 1, see row IV). Here, we focused on an acidic protein (isoelectric point [pI] = 4.1, molecular mass = 66 kDa) whose contents were temporarily decreased after the busulfan treatment and recovered along with the resumption of spermatogenesis, as shown in Figure 3. It was strongly suggested that such a protein was localized in the spermatogenic cells to be categorized into group III. This protein was identified as CABS1 (testis development protein NYD-SP26: 4931407G18Rik) by TOF-MS. CABS1 was originally identified as one of the testis development- and spermatogenesis-related genes both in human and mouse testes using cDNA microarrays, but neither the localization nor the physiological function of CABS1 in testis has been characterized yet [40].

The complete sequence of Cabs1 mRNA was determined in combination with RT-PCR and 5′-RACE and 3′-RACE methods using the total RNA fraction prepared from the adult mouse testis (Supplemental Fig. S1). The nucleotide sequence of Cabs1 thus obtained was the same as that of “BC 049750,” except the addition of nine nucleotides, ACTAAGCCC, to its 5′ terminus.

Expression and Localization of Cabs1 in Testis

The distribution of the Cabs1 mRNA among various mouse tissues was examined by RT-PCR and Northern blot analyses as described in Materials and Methods. As shown in Figure 4, a–c, the Cabs1 mRNA was detected only in testis. It was also found that the contents of the Cabs1 mRNA in testis were changed exactly with the same tendency as those of CABS1 after the treatment with busulfan (Fig. 4d).

The localization of the Cabs1 mRNA and CABS1 in testis were examined by in situ hybridization and immunohistochemical analyses, respectively. As shown in Figure 5, b and c, Cabs1 mRNA was specifically expressed in germ cells, which was first detected in the elongate spermatids at step 10 in stage X of the seminiferous epithelium cycle of the mouse. The maximal intensity of the hybridization signals was observed in the elongate spermatids at steps 13 and 14 during the stages from I to III.

The antisera against CABS1, which were prepared as described in Materials and Methods, specifically reacted with CABS1 among the proteins extracted from mouse testis. Figure 5, e and f, shows that CABS1 was localized in the elongate spermatids at steps 13 to 16 in the seminiferous epithelium of stages I to VIII. The expression patterns of Cabs1 mRNA and CABS1 in spermatogenesis were summarized in Figure 5g.

Furthermore, although some portions of immunoreactivity were thrown away in the residual body during spermiation, it was found that CABS1 was still present, specifically in the principal piece of flagellum of mature sperm in the cauda epididymis (Fig. 6).

Analysis of Calcium-Binding Activity of CABS1

It has been reported that the gene of the human homolog of Cabs1 is located within the gene cluster of the secretory calcium-binding phosphoproteins, such as casein, statherin, histatin, and enamel matrix proteins [41]. This report prompted us to analyze the calcium-binding activity of CABS1. As shown in Figure 7, both methods to detect the calcium-binding proteins, Stains-all staining and ruthenium red binding, proved that CABS1 bound calcium in a specific manner. These results strongly suggest that CABS1 is a new member of sperm-specific calcium-binding protein.

As shown in Figure 8, the recombinant CABS1 protein induced only the J band at 600–650 nm of Stains-all in a dose-dependent manner, but not the γ band at 500–510 nm. The addition of 10 mM CaCl2 reduced the J band by displacing the dye from the recombinant CABS1.

Furthermore, it was found that CABS1 in the mature sperm migrated to more a basic pH area (pI = 5.8) than the testicular protein on 2-DE, as shown in Figure 9. Preincubation of the proteins extracted from testis with 5 mM CaCl2 prior to the first-dimensional electrofocusing resulted in the translocation of CABS1 to the position of the sperm CABS1 on 2-DE. In turn, when the protein extracts of the cauda epididymal sperm were preincubated with 5 mM EDTA and separated by 2-DE, CABS1 migrated to the position of testicular CABS1 (pI = 4.1). These results indicate that the calcium binding to CABS1 occurs during the process of sperm maturation in the epididymis.


In the present study, spermatogenesis was temporarily ceased by a single intraperitoneal injection of a lower dose of busulfan (20 mg/kg) than that used for the experiments of germ cell transplantation [913]. At this dose, busulfan should act only on the proliferating germ cells, because the round spermatids normally completed spermiogenesis and then were spermiated. The testes at the various stages of the first cycle of the recovered spermatogenesis provide good materials to analyze the genes showing the spatiotemporally specific expression during the spermatogenesis.

In mouse, it takes about 5 wk from birth to complete the first cycle of spermatogenesis. These processes have been extensively used for the analysis of stage-specific gene expression in spermatogenesis. Most of those studies have been done at the transcriptional level by Northern blot analysis, RT-PCR, or cDNA microarray, but not at the protein level because the weight of testis is too small. Furthermore, the postnatal differentiation of Leydig cells into the adult type occurs by puberty, which makes the analysis of those processes complicated [42, 43]. Here, we used the sexually mature mice, which made it possible to extract enough materials for the proteome analysis and to exclude the changes involved in the differentiation of the somatic cells in testis throughout the first cycle of the recovered spermatogenesis induced by busulfan. Although it is known that busulfan selectively acts on the differentiated spermatogonia and spermatocytes even at 40 mg/kg, one must be careful to distinguish the changes in spermatogenesis from the pharmacological side effects of busulfan.

Profiling the testicular protein spots on 2-DE into three groups as shown in Table 1 is useful to select proteins that are expressed in the spermatogenic cells. Furthermore, the duration necessary for the recovery of a protein into the busulfan-treated testis was shown to depend on the stage of the spermatogenesis where the protein is expressed. For example, we identified a protein that once disappeared from testis and turned up again prior to CABS1 as superkiller viralicidic activity 2-like 2, official symbol SKIV2L2, a predicted DEAD-box RNA helicase (accession no. NP_082427 in GenPept database). It was for the first time shown to be expressed specifically in spermatocytes in the mouse testis by in situ hybridization (data not shown).

Cabs1 mRNA was found to be specifically expressed in the elongate spermatids at steps 10–16. No signals were observed in either spermatogonia, spermatocytes, round spermatids, or the somatic cells. Although postmeiotic expression has been reported in number of genes, some of those transcriptions, such as LDH-C4, acrosin, RT-7, and c-mos, have begun before meiosis, which continues into the elongate spermatids [4447]. On the other hand, protamine (Prm) and SP-10 (Acrv) genes are transcribed in the haploid cells during the steps of round spermatids [48, 49]. It has been suggested that mRNAs can hardly be transcribed after the condensation of chromatin. So, the onset of Cabs1 transcription seems to occur at the latest periods in spermatogenesis.

Furthermore, immunohistochemical analysis revealed the restricted expression of CABS1 protein to the elongate spermatids at steps 13–16, which is slightly later than the transcription of mRNA. Such a delay of protein expression during spermiogenesis is well known as a posttranscriptional control, which is very important for the completion of the final processes of spermiogenesis, including acrosome formation, tail formation, chromatin condensation, elongation of nucleus, cytoplasm removal, and spermiation [45, 48, 5052]. It is very interesting to explore the regulatory mechanisms of such highly spatiotemporally specific gene expression in the haploid germ cells.

CABS1 was first reported as one of the genes highly expressed in human testis by cDNA microarray analysis, although its function was not known [18]. Then, its gene was shown to locate within the secretory calcium-binding phosphoprotein gene cluster on human chromosome 4q13, where the genes for caseins, enamel matrix proteins, and some salivary proteins were localized [41]. In mouse, Cabs1 gene was also found to reside conservatively within the similar gene cluster on chromosome 5. In the present study, the physiological function of CABS1 has been for the first time identified to be a calcium-binding protein.

Along with the morphological changes, the signal transduction system is also built up during spermiogenesis. It is well accepted that Ca2+ plays central roles in the regulation of sperm cell function. Although sperm do not have endoplasmic reticulum, which is an essential component in somatic cells to control the intracellular concentrations of calcium ([Ca2+]i), it is suggested that mammalian sperm store Ca2+ at least both in the acrosome and neck regions, where InsP3 receptor, ryanodine receptor, secretory pathway Ca2+-ATPase 1 (SPCA 1, official symbol ATP2C1), and sarcoplasmic/endoplasmic reticulum Ca2+-ATPase 2 (SERCA 2, official symbol ATP2A2) mediate Ca2+ mobilization [5357]. It is also reported that sperm possess Ca2+-mobilizing components in the plasma membranes; Ca2+-permeable channels, such as CATSPERs and voltage-operated Ca2+ channels, and Ca2+-clearance agents, such as ATP-driven Ca2+ pumps (PMCAs, official symbol ATP2Bs) and Na+/Ca2+ exchangers [5862]. These proteins must be localized to their proper sites during spermiogenesis to exert their activities in responding to the signals that control sperm motility and fertilizing activity.

Furthermore, several calcium-binding proteins as well as calmodulin are also suggested to play important roles in the calcium signaling in sperm. Calreticulin has been shown to colocalize with InsP3 receptor in the acrosome, in the equatorial segment, and in vesicular structures in the cytoplasmic droplets of the neck region and regulate [Ca2+]i in sperm during capacitation and the acrosome reaction [63]. Calcium-binding proteins localizing to the principal piece of flagellum in association with the fibrous sheath, CABYR/FSCB, are also suggested to regulate hyperactivation and capacitation [64, 65]. In this connection, it is very interesting that CABS1 has been proven to be a novel member of the calcium-binding proteins and to be present in the mature sperm in the cauda epididymis. CABS1 was shown to localize to the principal piece of flagellum in mature sperm, which is a localization similar to CABYR/FSCB. Although the physiological importance of CABS1 in sperm remains to be concretely demonstrated, these results lead to the hypothesis that CABS1 is involved in the control of sperm motility and fertility.

By the analyses of nucleotide and deduced amino acid sequences, it was found that CABS1 did not contain any known calcium-binding motifs, such as EF-hand. So, the calcium-binding activity in CABS1 seems to be due to its high contents of acidic residues in the same manner as calsequestrin, calreticulin, and CABYR/FSCB [6366]. In this connection, it is interesting that CABS1 was stained blue by Stains-all. The metachromatic cationic carbocyanine dye Stains-all stains several calcium-binding proteins blue or purple, and other proteins red or pink, suggesting that this dye might be able to identify potential calcium-binding proteins [67]. In the present study, well-known calcium-binding proteins, such as tubulin and calreticulin, in addition to CABS1 were also identified by TOF-MS analysis directly with the spots on the 2-DE gel stained by the Stains-all, as shown in Figure 7a. Calreticulin was identified as an abundant protein in spermatozoa [63], whose contents were similar to the sum of alpha- and beta-tubulins as shown in Figure 7b. Although both CABS1 and beta-tubulin (spot 2) are less sensitive to CBB staining, Stains-all clearly recognizes them. These results indicate that Stains-all staining is a useful tool for electrophoretic analysis of calcium-binding proteins. As shown in Figure 7a, although beta-tubulin was stained blue by Stains-all, alpha-tubulin (spot 3) was stained red. In accordance with this, it has been reported that Stains-all selectively stains isoforms of axonemal beta-tubulin blue following isoelectric focusing, whereas those of alpha-tubulin are stained red [68].

It is known that different calcium-binding proteins interact differently with the dye, yielding different spectral bands, either the J band (600–650 nm) or the γ band (500–520 nm) or both [69, 70]. This enables the distinction of the possible structural differences among calcium-binding proteins. Binding of Stains-all to CABS1 was shown to induce only the J band dose dependently, which was similar in spectral properties to the complexes of Stains-all with parvalbumin [22], β-crystallin [71], and RVCaB [72]. It has been suggested that the J band is induced by dye binding to anionic sites in the globular or compact conformations of proteins [69]. It is very interesting that acidic amino acid residues are abundantly present in CABS1.

Furthermore, it was found that CABS1 in the cauda epididymal mature sperm migrated on 2-DE to a more basic area than that in testis. Such translocation indicates the differences of the net charge of acidic residues in CABS1 between testicular immature sperm and epididymal mature sperm, which are caused by calcium binding, as reported in the calcium binding to calreticulin [63]. It is well known that some highly acidic proteins show anomalous behavior in SDS-PAGE, migrating to the position with higher molecular mass than expected and restoring normal electrophoretic migration by neutralization of the negative charges [73, 74]. The testicular CABS1 migrated as a 66-kDa protein on 2-DE, although its true molecular mass is close to 42 kDa (Table 1). It was found that CABS1 in the cauda epididymal mature sperm shifted downward, 58 kDa, as shown in Figure 9f, to approach its true molecular mass, suggesting that the calcium bound to the protein in the mature sperm. This was confirmed by the results that preincubation of testicular extract with 10 mM CaCl2 shifted the position of CABS1 on 2-DE to that of the mature sperm. On the other hand, when the mature sperm extract was preincubated with 5 mM EDTA, CABS1 was migrated to the acidic position of testicular CABS1 on 2-DE. CABS1 reversibly shifted the electrophoretic migration between the two positions (pI = 4.1; 66 kDa) and (pI = 5.8; 58 kDa) in dependence on the calcium binding. These results strongly suggest that calcium binding to CABS1 occurs or greatly increases in sperm after spermiation and during its transit through the epididymis, and that CABS1 plays important roles in the control of the calcium signaling as a Ca2+ storage protein in the mature sperm.


We would like to thank Dr. Jun Yanagisawa and Ms. Mitsue Arimoto (University of Tsukuba) for assistance with mass spectrometry.


  1. R. M. Sharpe Regulation of spermatogenesis. In: E. Knobil and J. D. Neill . The Physiology of Reproduction, vol. 1, 2nd ed. . New York: Raven Press;. 1994. : 1363–1434. Google Scholar

  2. L. D. Russell, R. A. Ettlin, A. P. Sinha Hikim, and E. D. Clegg . Mammalian spermatogenesis. In: L. D. Russell, R. A. Ettlin, A. P. Sinha Hikim, and E. D. Clegg . Histological and Histopathological Evaluation of the Testis, 1st ed. . Clearwater, FL: Cache River Press;. 1990. : 1–40. Google Scholar

  3. G. F. Weinbauer and J. Wessels . ‘Paracrine’ control of spermatogenesis. Andrologia 1999. 31:249–262. Google Scholar

  4. K. Willison and A. Ashworth . Mammalian spermatogenic gene expression. Trends Genet 1987. 3:351–355. Google Scholar

  5. N. B. Hecht Molecular mechanisms of male germ cell differentiation. Bioessays 1998. 20:555–561. Google Scholar

  6. B. Jegou, C. Pineau, and A. Dupair . Paracrine control of testis function. In: C. Wang Male Reproductive Function (Endocrine Updates. ). Boston: Kluwer Academic Publishers;. 1999. : 41–64. Google Scholar

  7. H. Tanaka, M. Nozaki, K. Yomogida, and Y. Nishimune . Cloning and characterization of male germ-cell-specific genes. In: F. F. G. Rommerts and K. J. Teerds . Testicular Tangrams. . Berlin: Springer Verlag;. 2002. : 53–73. Google Scholar

  8. E. M. Eddy Male germ cell gene expression. Recent Prog Horm Res 2002. 57:103–128. Google Scholar

  9. R. L. Brinster and M. R. Avarbock . Germline transmission of donor haplotype following spermatogonial transplantation. Proc Natl Acad Sci U S A 1994. 91:11303–11307. Google Scholar

  10. R. L. Brinster and J. W. Zimmermann . Spermatogenesis following male germ-cell transplantation. Proc Natl Acad Sci U S A 1994. 91:11298–11302. Google Scholar

  11. T. Ogawa, I. Dobrinski, and R. L. Brinster . Recipient preparation is critical for spermatogonial transplantation in the rat. Tissue Cell 1999. 31:461–472. Google Scholar

  12. C. J. Brinster, B. Y. Ryu, M. R. Avarbock, L. Karagenc, R. L. Brinster, and K. E. Orwig . Restoration of fertility by germ cell transplantation requires effective recipient preparation. Biol Reprod 2003. 69:412–420. Google Scholar

  13. A. Honaramooz, E. Behboodi, C. L. Hausler, S. Blash, S. Ayres, C. Azuma, Y. Echelard, and I. Dobrinski . Depletion of endogenous germ cells in male pigs and goats in preparation for germ cell transplantation. J Androl 2005. 26:698–705. Google Scholar

  14. I. Buggia, F. Locatelli, M. B. Regazzi, and M. Zecca . Busulfan. Ann Pharmacother 1994. 28:1055–1062. Google Scholar

  15. S. Haddad, T. L. Carvalho, J. A. Anselmo-Franci, S. O. Petenusci, and A. L. Favaretto . Ultrasound stimulation of rat testes damaged by busulfan. Ultrasound Med Biol 1997. 23:1421–1425. Google Scholar

  16. Y. J. Choi, D. W. Ok, D. N. Kwon, J. I. Chung, H. C. Kim, S. M. Yeo, T. Kim, H. G. Seo, and J. H. Kim . Murine male germ cell apoptosis induced by busulfan treatment correlates with loss of c-kit-expression in a Fas/FasL- and p53-independent manner. FEBS Lett 2004. 575:41–51. Google Scholar

  17. M. Kanatsu-Shinohara, S. Toyokuni, T. Morimoto, S. Matsui, T. Honjo, and T. Shinohara . Functional assessment of self-renewal activity of male germline stem cells following cytotoxic damage and serial transplantation. Biol Reprod 2003. 68:1801–1807. Google Scholar

  18. S. Jiahao, Z. H. Zuomin, and L. Jianmin . Preparation of human testicular cDNA microarray and initial research of gene expression library related to spermatogenesis. In: H. S. Chan Epithelial Cell Biology—A Primer. . Beijing: Press of Military Medical Science;. 2000. : 274–277. Google Scholar

  19. J. Noguchi, H. Hikono, S. Sato, G. Watanabe, K. Taya, S. Sasamoto, and Y. Hasegawa . Ontogeny of inhibin secretion in the rat testis: secretion of inhibin-related proteins from fetal Leydig cells and of bioactive inhibin from Sertoli cells. J Endocrinol 1997. 155:27–34. Google Scholar

  20. K. P. Campbell, D. H. MacLennan, and A. O. Jorgensen . Staining of the Ca2+-binding proteins, calsequestrin, calmodulin, troponin C, and S-100, with the cationic carbocyanine dye “Stains-all”. J Biol Chem 1983. 258:11267–11273. Google Scholar

  21. J. H. Charuk, C. A. Pirraglia, and R. A. Reithmeier . Interaction of ruthenium red with Ca2(+)-binding proteins. Anal Biochem 1990. 188:123–131. Google Scholar

  22. C. G. Caday and R. F. Steiner . The interaction of calmodulin with the carbocyanine dye (Stains-all). J Biol Chem 1985. 260:5985–5990. Google Scholar

  23. M. Nakamura, M. Moriya, T. Baba, Y. Michikawa, T. Yamanobe, K. Arai, S. Okinaga, and T. Kobayashi . An endoplasmic reticulum protein, calreticulin, is transported into the acrosome of rat sperm. Exp Cell Res 1993. 205:101–110. Google Scholar

  24. R. Huo, Y. F. Zhu, X. Ma, M. Lin, Z. M. Zhou, and J. H. Sha . Differential expression of glucose-regulated protein 78 during spermatogenesis. Cell Tissue Res 2004. 316:359–367. Google Scholar

  25. G. Aumuller and J. Seitz . Immunocytochemical localization of actin and tubulin in rat testis and spermatozoa. Histochemistry 1988. 89:261–267. Google Scholar

  26. L. A. Lopez-Fernandez and J. del Mazo . The cytosolic aldehyde dehydrogenase gene (Aldh1) is developmentally expressed in Leydig cells. FEBS Lett 1997. 407:225–229. Google Scholar

  27. J. L. Gelly, J. P. Richoux, and G. Grignon . Immunolocalization of albumin and transferrin in germ cells and Sertoli cells during rat gonadal morphogenesis and postnatal development of the testis. Cell Tissue Res 1994. 276:347–351. Google Scholar

  28. L. J. Zhu, S. D. Zong, D. M. Phillips, A. J. Moo-Young, and C. W. Bardin . Changes in the distribution of intermediate filaments in rat Sertoli cells during the seminiferous epithelium cycle and postnatal development. Anat Rec 1997. 248:391–405. Google Scholar

  29. T. Kobayashi, T. Kaneko, Y. Iuchi, S. Matsuki, M. Takahashi, I. Sasagawa, T. Nakada, and J. Fujii . Localization and physiological implication of aldose reductase and sorbitol dehydrogenase in reproductive tracts and spermatozoa of male rats. J Androl 2002. 23:674–683. Google Scholar

  30. K. L. Asquith, A. J. Harman, E. A. McLaughlin, B. Nixon, and R. J. Aitken . Localization and significance of molecular chaperones, heat shock protein 1, and tumor rejection antigen gp96 in the male reproductive tract and during capacitation and acrosome reaction. Biol Reprod 2005. 72:328–337. Google Scholar

  31. J. E. Welch and M. G. O'Rand . Characterization of a sperm-specific nuclear autoantigenic protein. II. Expression and localization in the testis. Biol Reprod 1990. 43:569–578. Google Scholar

  32. J. Tsuchida, Y. Nishina, N. Wakabayashi, M. Nozaki, Y. Sakai, and Y. Nishimune . Molecular cloning and characterization of meichroacidin (male meiotic metaphase chromosome-associated acidic protein). Dev Biol 1998. 197:67–76. Google Scholar

  33. X. Q. Wu, S. Lefrancois, C. R. Morales, and N. B. Hecht . Protein-protein interactions between the testis brain RNA-binding protein and the transitional endoplasmic reticulum ATPase, a cytoskeletal gamma actin and Trax in male germ cells and the brain. Biochemistry 1999. 38:11261–11270. Google Scholar

  34. B. Gold, H. Fujimoto, J. M. Kramer, R. P. Erickson, and N. B. Hecht . Haploid accumulation and translational control of phosphoglycerate kinase-2 messenger RNA during mouse spermatogenesis. Dev Biol 1983. 98:392–399. Google Scholar

  35. M. Moriya, M. Ochiai, H. J. Yuasa, N. Suzuki, and M. Yazawa . Identification of Ca2+-dependent calmodulin-binding proteins in rat spermatogenic cells as complexes of the heat-shock proteins. Mol Reprod Dev 2004. 69:316–324. Google Scholar

  36. H. Ohtani, H. Wakui, T. Ishino, A. Komatsuda, and A. B. Miura . An isoform of protein disulfide isomerase is expressed in the developing acrosome of spermatids during rat spermiogenesis and is transported into the nucleus of mature spermatids and epididymal spermatozoa. Histochemistry 1993. 100:423–429. Google Scholar

  37. P. J. O'Shaughnessy and L. Murphy . Cytochrome P-450 17 alpha-hydroxylase protein and mRNA in the testis of the testicular feminized (Tfm) mouse. J Mol Endocrinol 1993. 11:77–82. Google Scholar

  38. R. A. Srivastava, N. Bhasin, and N. Srivastava . Apolipoprotein E gene expression in various tissues of mouse and regulation by estrogen. Biochem Mol Biol Int 1996. 38:91–101. Google Scholar

  39. S. Y. Huang, M. F. Tam, Y. T. Hsu, J. H. Lin, H. H. Chen, C. K. Chuang, M. Y. Chen, Y. T. King, and W. C. Lee . Developmental changes of heat-shock proteins in porcine testis by a proteomic analysis. Theriogenology 2005. 64:1940–1955. Google Scholar

  40. J. Sha, Z. Zhou, J. Li, L. Yin, H. Yang, G. Hu, M. Luo, H. C. Chan, and K. Zhou . Spermatogenesis study group. Identification of testis development and spermatogenesis-related genes in human and mouse testes using cDNA arrays. Mol Hum Reprod 2002. 8:511–517. Google Scholar

  41. K. Kawasaki and K. M. Weiss . Mineralized tissue and vertebrate evolution: the secretory calcium-binding phosphoprotein gene cluster. Proc Natl Acad Sci U S A 2003. 100:4060–4065. Google Scholar

  42. L. Benton, L. X. Shan, and M. P. Hardy . Differentiation of adult Leydig cells. J Steroid Biochem Mol Biol 1995. 53:61–68. Google Scholar

  43. P. J. O'Shaughnessy, L. Willerton, and P. J. Baker . Changes in Leydig cell gene expression during development in the mouse. Biol Reprod 2002. 66:966–975. Google Scholar

  44. K. Thomas, J. Del Mazo, P. Eversole, A. Bellve, Y. Hiraoka, S. S. Li, and M. Simon . Developmental regulation of expression of the lactate dehydrogenase (LDH) multigene family during mouse spermatogenesis. Development 1990. 109:483–493. Google Scholar

  45. S. Kashiwabara, Y. Arai, K. Kodaira, and T. Baba . Acrosin biosynthesis in meiotic and postmeiotic spermatogenic cells. Biochem Biophys Res Commun 1990. 173:240–245. Google Scholar

  46. F. A. Van der Hoorn, H. A. Tarnasky, and S. K. Nordeen . A new rat gene RT7 is specifically expressed during spermatogenesis. Dev Biol 1990. 142:147–154. Google Scholar

  47. E. C. Coucouvanis and P. P. Jones . Changes in protooncogene expression correlated with general and sex-specific differentiation in murine primordial germ cells. Mech Dev 1993. 42:49–58. Google Scholar

  48. P. Mali, A. Kaipia, M. Kangasniemi, J. Toppari, M. Sandberg, N. B. Hecht, and M. Parvinen . Stage-specific expression of nucleoprotein mRNAs during rat and mouse spermiogenesis. Reprod Fertil Dev 1989. 1:369–382. Google Scholar

  49. B. E. Kurth, K. Klotz, C. J. Flickinger, and J. C. Herr . Localization of sperm antigen SP-10 during the six stages of the cycle of the seminiferous epithelium in man. Biol Reprod 1991. 44:814–821. Google Scholar

  50. T. Kido and Y. F. Lau . The rat Tspy is preferentially expressed in elongated spermatids and interacts with the core histones. Biochem Biophys Res Commun 2006. 350:56–67. Google Scholar

  51. H. Zheng, C. J. Stratton, K. Morozumi, J. Jin, R. Yanagimachi, and W. Yan . Lack of Spem1 causes aberrant cytoplasm removal, sperm deformation, and male infertility. Proc Natl Acad Sci U S A 2007. 104:6852–6857. Google Scholar

  52. H. Iida, M. Doiguchi, H. Yamashita, S. Sugimachi, J. Ichinose, T. Mori, and Y. Shibata . Spermatid-specific expression of Iba1, an ionized calcium binding adapter molecule-1, in rat testis. Biol Reprod 2001. 64:1138–1146. Google Scholar

  53. L. D. Walensky and S. H. Snyder . Inositol 1,4,5-trisphosphate receptors selectively localized to the acrosomes of mammalian sperm. J Cell Biol 1995. 130:857–869. Google Scholar

  54. C. V. Harper, C. L. Barratt, and S. J. Publicover . Stimulation of human spermatozoa with progesterone gradients to simulate approach to the oocyte. Induction of [Ca(2+)](i) oscillations and cyclical transitions in flagellar beating. J Biol Chem 2004. 279:46315–46325. Google Scholar

  55. C. Harper, L. Wootton, F. Michelangeli, L. Lefievre, C. Barratt, and S. Publicover . Secretory pathway Ca(2+)-ATPase (SPCA1) Ca(2)+ pumps, not SERCAs, regulate complex [Ca(2+)](i) signals in human spermatozoa. J Cell Sci 2005. 118:1673–1685. Google Scholar

  56. C. Lawson, V. Dorval, S. Goupil, and P. Leclerc . Identification and localisation of SERCA 2 isoforms in mammalian sperm. Mol Hum Reprod 2007. 13:307–316. Google Scholar

  57. S. Publicover, C. V. Harper, and C. Barratt . [Ca2+]i signalling in sperm–making the most of what you've got. Nat Cell Biol 2007. 9:235–242. Google Scholar

  58. H. Qi, M. M. Moran, B. Navarro, J. A. Chong, G. Krapivinsky, L. Krapivinsky, Y. Kirichok, I. S. Ramsey, T. A. Quill, and D. E. Clapham . All four CatSper ion channel proteins are required for male fertility and sperm cell hyperactivated motility. Proc Natl Acad Sci U S A 2007. 104:1219–1223. Google Scholar

  59. A. Darszon, J. J. Acevedo, B. E. Galindo, E. O. Hernandez-Gonzalez, T. Nishigaki, C. L. Trevino, C. Wood, and C. Beltran . Sperm channel diversity and functional multiplicity. Reproduction 2006. 131:977–988. Google Scholar

  60. K. Schuh, E. J. Cartwright, E. Jankevics, K. Bundschu, J. Liebermann, J. C. Williams, A. L. Armesilla, M. Emerson, D. Oceandy, K. P. Knobeloch, and L. Neyses . Plasma membrane Ca2+ ATPase 4 is required for sperm motility and male fertility. J Biol Chem 2004. 279:28220–28226. Google Scholar

  61. G. Wennemuth, D. F. Babcock, and B. Hille . Calcium clearance mechanisms of mouse sperm. J Gen Physiol 2003. 122:115–128. Google Scholar

  62. G. W. Okunade, M. L. Miller, G. J. Pyne, R. L. Sutliff, K. T. O'Connor, J. C. Neumann, A. Andringa, D. A. Miller, V. Prasad, T. Doetschman, R. J. Paul, and G. E. Shull . Targeted ablation of plasma membrane Ca2+-ATPase (PMCA) 1 and 4 indicates a major housekeeping function for PMCA1 and a critical role in hyperactivated sperm motility and male fertility for PMCA4. J Biol Chem 2004. 279:337:42–50. Google Scholar

  63. S. Naaby-Hansen, M. J. Wolkowicz, K. Klotz, L. A. Bush, V. A. Westbrook, H. Shibahara, J. Shetty, S. A. Coonrod, P. P. Reddi, J. Shannon, M. Kinter, N. E. Sherman, et al . Co-localization of the inositol 1,4,5-trisphosphate receptor and calreticulin in the equatorial segment and in membrane bounded vesicles in the cytoplasmic droplet of human spermatozoa. Mol Hum Reprod 2001. 7:923–933. Google Scholar

  64. S. Naaby-Hansen, A. Mandal, M. J. Wolkowicz, B. Sen, V. A. Westbrook, J. Shetty, S. A. Coonrod, K. L. Klotz, Y. H. Kim, L. A. Bush, C. J. Flickinger, and J. C. Herr . CABYR, a novel calcium-binding tyrosine phosphorylation-regulated fibrous sheath protein involved in capacitation. Dev Biol 2002. 242:236–254. Google Scholar

  65. Y. F. Li, W. He, K. N. Jha, K. Klotz, Y. H. Kim, A. Mandal, S. Pulido, L. Digilio, C. J. Flickinger, and J. C. Herr . FSCB, a novel protein kinase A-phosphorylated calcium-binding protein, is a CABYR-binding partner involved in late steps of fibrous sheath biogenesis. J Biol Chem 2007. 282:34104–34119. Google Scholar

  66. B. T. Scott, H. K. Simmerman, J. H. Collins, B. Nadal-Ginard, and L. R. Jones . Complete amino acid sequence of canine cardiac calsequestrin deduced by cDNA cloning. J Biol Chem 1988. 263:958–964. Google Scholar

  67. Y. Sharma, C. M. Rao, S. C. Rao, A. Gopala Krishna, T. Somasundaram, and D. Balasubramanian . Binding site conformation dictates the color of the dye Stains-all. J Biol Chem 1989. 264:20923–20927. Google Scholar

  68. L. Serrano, F. Wandosell, J. C. Diez, and J. Avila . The combined use of limited proteolysis and differential peptide staining for protein characterization. J Biochem Biophys Methods 1986. 12:281–287. Google Scholar

  69. Y. Sharma and D. Balasubramanian . Stains-all is a dye that probes the conformational features of calcium binding proteins. In: C. W. Heizmann Novel Calcium-Binding Proteins. . Berlin: Springer-Verlag;. 1991. : 51–61. Google Scholar

  70. C. G. Caday, P. K. Lambooy, and R. F. Steiner . The interaction of Ca2+-binding proteins with the carbocyanine dye stains-all. Biopolymers 1986. 25:1579–1595. Google Scholar

  71. Y. Sharma, C. M. Rao, M. L. Narasu, S. C. Rao, T. Somasundaram, A. Gopalakrishna, and D. Balasubramanian . Calcium ion binding to delta- and to beta-crystallins. The presence of the “EF-hand” motif in delta-crystallin that aids in calcium ion binding. J Biol Chem 1989. 264:12794–12799. Google Scholar

  72. K. Yuasa and M. Maeshima . Purification, properties, and molecular cloning of a novel Ca(2+)-binding protein in radish vacuoles. Plant Physiol 2000. 124:1069–1078. Google Scholar

  73. P. Graceffa, A. Jancso, and K. Mabuchi . Modification of acidic residues normalizes sodium sulfate-polyacrylamide gel electrophoresis of caldesmon and other proteins that migrate anomalously. Arch Biochem Biophys 1992. 297:46–51. Google Scholar

  74. V. S. Alves, D. C. Pimenta, E. Sattlegger, and B. A. Castilho . Biophysical characterization of Gir2, a highly acidic protein of Saccharomyces cerevisiae with anomalous electrophoretic behavior. Biochem Biophys Res Commun 2004. 314:229–234. Google Scholar

FIG. 1.

Effects of busulfan on spermatogenesis in mice. a) The adult mice were injected i.p. with various concentrations of busulfan. At 4 wk (open bars) and 9 wk (closed bar) after the treatment, mice were dissected, and 4-μm sections of testes were used for assessment of spermatogenesis. The results are expressed as a percentage of the seminiferous tubules containing spermatocytes per 200 seminiferous tubules. Data are mean ± SEM from three different experiments, each with three sets of determinations of 200 seminiferous tubules in the different regions of the testis. Statistical analysis was conducted by t test with the significance level at P < 0.05. Groups with different lowercase letters are significantly different. On 0 (b), 32 (c), 41 (d), and 77 (e) days after the treatment with 20 mg/kg busulfan, mice were dissected, and 4-μm sections of testes stained by hematoxylin and eosin were observed under the microscope. Insets are undifferentiated (f) and differentiated (g) spermatogonia nuclei. Bars = 50 μm (be) and 5 μm (f and g).


FIG. 2.

Profiles of testiscular proteins separated by 2-DE. The proteins extracted from testes 32 days after the injection of 200 μl of 50% DMSO with (b) or without (a) busulfan (20 mg/kg body weight) were separated by 2-DE. The 10% SDS-polyacrylamide gels were stained with CBB. The protein spots identified by mass spectrometry are indicated by the arrows and numbered from 1 to 17, which correspond to “Spot No.” in Table 1. The pIs 4.5, 5.2, and 5.8 are representative values of the identified spots for well-known proteins calreticulin, actin, and protein disulfide isomerase-associated 3, respectively. kda, kilodaltons.


FIG. 3.

Changes of the CABS1 contents in testis after the busulfan treatment. The testicular proteins were extracted at various intervals of time—0 (a), 32 (b), 41 (c), 56 (d), and 77 (e) days—after busulfan treatment and separated by 2-DE. CABS1 is indicated by the arrows. f) The intensity of the CABS1 spot (closed diamonds) on the 10% SDS-polyacrylamide gel was analyzed with the software PDQuest Version 6.2. The intensity of the actin spot is shown by open circles as an unchanged protein control. g) Western blot analysis of CABS1 protein in the testicular proteins separated by 10% SDS-polyacrylamide gel. Upper: Western blot analysis. Lower: CBB staining. kda, kilodaltons.


FIG. 4.

Northern blot analysis and RT-PCR of Cabs1. The total RNAs (10 μg each) prepared from mouse brain, heart, lung, thymus , liver, spleen, kidney, epididymis, and testis were electrophoresed (a), transferred to a nylon membrane, and probed with DIG-labeled cRNA probe (b). c) The RT-PCR analysis of Cabs1 mRNA expression in the various mouse organs as in a. Gapdh was used as a loading control. d) The RT-PCR analysis of Cabs1 mRNA in testis at various intervals of time after busulfan (20 mg/kg body weight) treatment.


FIG. 5.

Localization of Cabs1 mRNA and protein in the mouse testis. ac) Localization of Cabs1 mRNA analyzed by in situ hybridization. Frozen sections were hybridized with a DIG-labeled antisense (b and c) or sense (a) probe. df) Immunohistochemical localization of CABS1 protein in the mouse testis analyzed with anti-CABS1 antisera (e and f). Replacement of the antisera with the antisera previously neutralized with CABS1 antigen gives no specific staining (d). g) Schematic summary of the localization of Cabs1 mRNA and protein during spermiogenesis. Solid line and broken line represent the expression windows of Cabs1 mRNA and protein, respectively. Roman numerals in b, c, e, f, and g represent stages of the seminiferous epithelial cycles, and Arabic numbers in g represent steps of spermatid development. Bars = 50 μm.


FIG. 6.

Immunofluorescent detection of CABS1 protein in the cauda epididymal sperm. a, c, and e) Phase-contrast microscopic analysis of the cauda epididymal sperm. b and d) The localization of CABS1 in the cauda epididymal sperm was analyzed with anti-CABS1 antisera. f) Epididymal sperm incubated with antisera previously neutralized with CABS1 antigen were used as a negative control. Bars = 50 μm.


FIG. 7.

Detection of CABS1 protein by Stains-all and ruthenium red. Mouse testicular proteins were separated by 2-DE using 10% SDS-polyacrylamide gels and stained either with Stains-all (a) or CBB (b). Mouse testicular proteins separated by 2-DE were electroblotted onto PVDF membranes, which were incubated with (c) or without (d) 50 mM CaCl2 and then overlaid with ruthenium red solutions. Red arrows indicate the CABS1 spot. Spot 1 in a was identified as calreticulin, and spots 2 and 3 were identified as beta- and alpha-tubulin, respectively. kda, kilodaltons.


FIG. 8.

Absorption spectra of the complexes of Stains-all with the recombinant CABS1 protein. Various concentrations of the recombinant CABS1 were incubated with Stains-all as described in Materials and Methods, and absorption spectra were taken with a spectrophotometer. Solid line, dashed line, and broken line indicate Stains-all spectra in the presence of 0, 1, and 5 μg of the recombinant CABS1, respectively. Dotted line indicates Stains-all spectrum in the presence of 5 μg of the recombinant CABS1 and 10 mM CaCl2.


FIG. 9.

Differences in the behavior of CABS1 protein on the 2-DE gel between the testis and the cauda epididymal sperm. Proteins extracted from the mouse testis (a, c, e, and g) and the cauda epididymal sperm (b, d, f, and h) were separated by 2-DE. Western blot analyses of CABS1 protein both in the testis (e and g) and the cauda epididymal sperm (f and h) were done. The testicular protein extracts were incubated at 25°C for 30 min with (g) or without (e) 5 mM CaCl2 before 2-DE. The protein extracts of the mature sperm were also preincubated with (h) or without (f) 5 mM EDTA. a and b) CBB staining. c and d) Negative control of Western blot analysis with the neutralized antisera against CABS1. CABS1 is indicated by the arrow. kda, kilodaltons.



List of spots identified by MALDI-TOF-MS and bioinformatic analysis.



[1] Financial disclosure Supported by the Ministry of Education, Culture, Sports, Science and Technology of Japan.

Akihiro Kawashima, Boran A. H. Osman, Minoru Takashima, Akihiko Kikuchi, Sae Kohchi, Emiko Satoh, Michiko Tamba, Manabu Matsuda, and Naomichi Okamura "CABS1 Is a Novel Calcium-Binding Protein Specifically Expressed in Elongate Spermatids of Mice," Biology of Reproduction 80(6), (1 June 2009).
Received: 30 September 2008; Accepted: 1 January 2009; Published: 1 June 2009

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