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Sodium-Inorganic Phosphate Cotransporter NaP_i-IIb in the Epididymis and Its Potential Role in Male Fertility Studied in a Transgenic Mouse Model¹

Institute of Reproductive Medicine of the University,⁴ Münster, Germany College of Medicine,⁵ Wuhan University, Wuhan, People's Republic of China Institute of Physiology,⁶ University of Tübingen, Tübingen, Germany Department of Physiology,⁷ University of Zürich, Zürich, Switzerland

	ABSTRACT

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Analysis by cDNA microarrays showed that in the murine epididymis, NaP_i-IIb was the predominantly expressed epithelial isoform of the sodium-inorganic phosphate cotransporter and was markedly overexpressed in the proximal region in the infertile knockout (KO) compared to the fertile heterozygous (HET) c-ros transgenic mouse. The apparent up-regulation in the KO mouse confirmed by Northern and Western blot analyses could be explained by the absence of NaP_i-IIb from the initial segment of the HET epididymis, as revealed by immunohistochemistry, and its presence on the epithelial brush border throughout the proximal epididymis of KO mice, where differentiation of the initial segment fails to occur. Both NaP_i-IIb mRNA and protein were scarce or absent from the cauda epididymidis of both genotypes. A high content of inorganic phosphate was measured enzymatically in the HET cauda luminal fluid, with a 27% decrease in the KO mice. This decrease, presumably from a greater reabsorption of inorganic phosphate, particularly in the initial part of the KO epididymis, may disturb the normal process of sperm maturation in these infertile males. By contrast, no apparent consequences were observed for the transport of Na⁺ and Ca²⁺, the concentrations of which (26 mM and 30 µM, respectively) were measured by microelectrodes to be identical in the caudal fluid from both genotypes.

epididymis, gamete biology, male reproductive tract, sperm maturation, sperm motility and transport

	INTRODUCTION

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Mammalian spermatozoa produced in the testis are incapable of fertilizing eggs in vivo. Functional competence of the male gamete is acquired during transit through the epididymis, which provides a unique milieu for sperm maturation and storage in the tubule lumen by absorptive and secretory activities of the epididymal epithelium [1]. The essential role of the epididymis in fertility is highlighted in the transgenic model of the proto-oncogene receptor protein kinase c-ros knockout (KO) mice, which are healthy but infertile animals whose initial part of the epididymis is not differentiated during puberty into the characteristic initial segment [2]. These mice deposit the normal number of motile sperm into the uterus during normal mating, but the ejaculated spermatozoa are swollen into abnormal shapes in the uterus and fail to migrate into the oviduct [3] because of defective cell volume regulation [4, 5]. Because the sperm defect is apparently caused by epididymal malfunction [6], the present investigation is focused on the search for abnormal epididymal epithelial and luminal factors to understand how the epididymis regulates sperm function.

Comparative gene expression profiling has been used in the initial screening of candidate genes for the relevant epithelial function that may result in an abnormal epididymal milieu in the infertile animals. One of these is the sodium-dependent glutamate transporter EAAC1, which is down-regulated in the c-ros KO mouse proximal epididymis and could partially contribute to the sperm defect in cell volume regulation [7, 8]. Another candidate gene is the sodium-inorganic phosphate cotransporter (NaP_i-IIb), which was found to be overexpressed in the proximal region of the epididymis of the c-ros homozygous KO mice compared to the fertile, heterozygous (HET) animals. The NaP_i-II membrane transporters are highly regulated systems employed by epithelia for inorganic phosphate (P_i) homeostasis. Whereas the isoform NaP_i-IIa is expressed only in the kidney and the brain, the phylogenically older isoform NaP_i-IIb was first cloned from the small intestine [9] and is expressed in several other epithelia (for review, see [10]). In the epididymis, the control of P_i level would be crucial in view of its very high concentrations in the luminal fluid reported in the literature. These amount to 16 mM in the distal end of the tubule in rats [11] and 24 mM in the vas deferens of men [12], presenting a risk for the precipitation of calcium phosphate. Because NaP_i-II could serve as a backup system for Na⁺ reabsorption in the proximal kidney tubule [13], it is possible that NaP_i-IIb is also involved in the highly active Na⁺ reabsorption of the epididymis.

In this report of NaP_i-IIb in the epididymis, we have quantified the gene as well as protein expression profiles, and we have established the immunological localization with regional differences within the organ. Concentrations of Na⁺, Ca²⁺, and P_i in the epididymal fluid bathing the fertile and infertile murine spermatozoa have also been measured to gain insight regarding the potential role of epididymal NaP_i-IIb in male fertility regulation.

	MATERALS AND METHODS

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Animals and Tissue Preparation

Male and female mice that are heterozygous for targeted deletions of c-ros [2, 14] were generously donated as breeding pairs by Dr. E. Riethmacher and Prof. Dr. C. Birchmeier from the Max-Delbrück Centre of Molecular Medicine (Berlin, Germany), where the transgenic animals were generated. The transgenic colony was maintained at 22°C under a 12L:12D photoperiod. Experimental studies were conducted according to the German Federal Law on the Care and Use of Laboratory Animals (licenses A38/2002 and G61/2001). Because HET male mice showed normal fertility [2] and sperm motility [4] without any difference in phenotype compared to the wild-type mice, they were used as normal controls.

Each epididymis from the HET and KO mice was dissected clean of connective tissue and divided into four segments: the initial segment (or the equivalent gross anatomical region in the KO mice) and the remaining caput, corpus, and cauda regions. The tissues were snap-frozen in liquid nitrogen and stored at -80°C until use. For some gene-chip array experiments, the most proximal part of the epididymis, consisting in the HET mice of the initial segment and proximal caput region and in the KO mice of the equivalent gross anatomical region, were isolated, frozen in liquid nitrogen, and stored at -80°C. For other array experiments, whole epididymides from both genotypes were divided into the caput, corpus, and cauda regions for comparison.

RNA Extraction, Reverse Transcription-Polymerase Chain Reaction, and Northern Blot Analysis

From 50 to 100 mg of frozen tissue of various segments were homogenized by a microdismembrator (Braun Biotech International, Melsungen, Germany), and total RNA was extracted using the Qiagen RNeasy Midi kit (Qiagen, Heidelberg, Germany) and quantified spectrophotometrically (BioPhotometer; Eppendorf, Hamberg, Germany). For the detection of NaP_i-IIb mRNA and the generation of cDNA as template for Northern blot analysis, conventional reverse transcription-polymerase chain reaction (RT-PCR) was performed as previously described [15] using the forward oligo-primer 5'-CGGACAGTTCTTCAGCAACA-3' and the reverse primer 5'-CAGAATGTCTGGGGCATCTT-3', resulting in an amplicon of 403 base pairs (bp). Northern blot hybridization of the extracted total RNA, using 15 µg of each sample, was performed similar to the method described previously [15].

Gene Expression Analysis by AffyMetrix Gene Chip

With each gene chip (MG U74A; Affymetrix, Santa Clara, CA), 20 µg of total RNA from each epididymal region were analyzed according to procedures recommended by Affymetrix. Double-stranded cDNA reverse-transcribed from the RNA sample was used as template to transcribe biotin-labeled cRNA. After hybridization of the labeled probe onto the gene chip, the marker was visualized by conjugate incubation in a Fluidics station 400 (Affymetrix) and scanned with the GeneArray scanner. Quantification of the digitized fluorescence signals generated mean values, and the differences between four pairs of gene chips (KO and HET samples processed in parallel in each experiment) were analyzed by the GeneChip Suite Analysis Software (Affymetrix).

Western Blot Analysis and Quantification

Frozen tissues were ground to powder in 100 µl lysis buffer using the microdismembrator and taken up in a total of 0.5 ml of lysis buffer (125 mM NaCl, 25 mM Hepes, 10 mM EDTA, 10 mM sodium pyrophosphate, 10 mM NaF, 0.1% (w/v) SDS, 0.5% (w/v) deoxycholate, and 1% (v/v) Triton X-100 at pH 7.3 containing 10 µl of protease-inhibitor cocktail [Sigma, St. Louis, MO] and 1 mM Na₃VO₄). The suspension was vortexed and centrifuged for 30 min at 15 000 x g at 4°C. The tissue extract was estimated for its protein concentration using the bicinchoninic acid (BCA) protein assay and stored at -20°C.

Polyacrylamide gel electrophoretic separation of proteins was carried out using 10% Bis-Tris precast gels (8 x 8 cm; thickness, 1 mm; NuPage; Invitrogen, Carlsbad, CA) according to the manufacturer's instructions with 30 µg of protein sample in each lane after heating at 70°C for 10 min in the presence of dithiothreitol. Separated proteins were transferred onto ECL-Hybond membranes (Amersham Biosciences, Little Clalfont, UK) at 35 V for 100 min. After blocking with 5% milk powder at 4°C overnight, the membrane was incubated with the purified rabbit antibody against NaP_i-IIb (produced as described in Hilfiker et al. [9]) at a final dilution of 1:2400 for 1 h at room temperature and with the secondary antibody (peroxidase-conjugated goat anti-rabbit immunoglobulin [Ig] G; Sigma) at 1:12 000 dilution for 1 h. Peroxidase-bound protein bands were visualized using the ECL-Plus method (Amersham Biosciences). Intensities of bands on films were quantified using the line densitometer software (ChemImage System, IS4400; Alpha Innotech Corp., San Laendro, CA).

To check for specificity of the enhanced chemiluminescence signals for NaP_i-IIb, blotted membranes were processed with normal rabbit IgG (8 µg/ml) replacing the primary antibody or with primary antibody adsorbed with the antigen peptide (60 µl of a 10 mg/ml concentration with 5 µl of antibody diluted 1:1 in glycerol).

Immunohistochemistry

Paraformaldehyde-fixed and paraffin-embedded tissues were cut into sections (thickness, 4 µm). After deparaffinization and rehydration, tissue sections were heated in a microwave oven for 25 min at 80°C in 0.05 M glycine buffer (pH 6.0) for antigen retrieval. After blocking with 5% normal goat serum in 1% bovine serum albumin in Tris-buffered saline, sections were incubated for 1 h at room temperature with the primary antibody (see above) at a dilution of 1:100 and for 60 min at room temperature with secondary antibody (1:100, goat anti-rabbit IgG conjugated with alkaline phosphatase; Sigma). Bound antibody conjugates were visualized by fuchsin substrate-chromogen (DAKO Corporation, Carpinteria, CA). Sections were counter-stained with Mayer hematoxylin and mounted in Faramount (DAKO). Negative controls for the immunostaining included replacement of the primary antibody with normal rabbit IgG (10 µg/ml) or with primary antibody after absorption with the antigen peptide (12 µl of a 10 mg/ml concentration with 1 µl of antibody diluted 1:1 in glycerol in a final volume of 100 µl of staining solution).

Fluorimetric Assay of P_i

The proximal vas deferens of freshly isolated epididymis was cannulated with a drawn-out polyvinylchloride catheter (Critchley Electrical Products Pty Ltd., Silverwater, Australia). The perfusion solution used had osmolalities of approximately 400 mmol/kg to mimic native epididymal fluid [4] and consisted of either sucrose with 10 mM Tris (pH 7.4) or NaCl with 100 mM Tris (pH 7.5). Luminal contents from both caudae epididymidum (3 µl in total, approximately half the volume comprising sperm cells according to values from other rodents [16]) were exuded from a cut end of the tubule in the proximal cauda region by retrograde perfusion from the vas deferens and transferred via a positive displacement pipette into 100 µl of the same solution. Sperm cells were removed by centrifugation at 4°C at 2000 x g for 2 min, and the supernatant was centrifuged again for 5 min before storage of the sperm-free fluid at -20°C. Protein concentrations of the samples were measured using the BCA assay.

Inorganic phosphate in samples diluted 1:50 with the assay buffer was measured in 96-well plates by a commercial kit (Kit A-12216; Molecular Probes, Leiden, The Netherlands). This is an enzymatic assay measuring resorufin as an end product after conversion of maltose into glucose by maltose phosphorylase using the P_i available in the sample. Emission at 590 nm with excitation at 530 nm was read in a fluorimetric plate reader (spectroMAX Gemini; Molecular Devices GmbH, Munich, Germany) after incubation for 45 min at 37°C. The same dilution of the perfusion solution was added to the assay blank and P_i standards (0.125–50 µM) to correct for any interference of the assay. Endogenous glucose, if any, did not contribute to any reading, because measurements made in the absence of maltose phosphorylase did not give any positive absorbance. Because the volume of the neat epididymal fluid was too small to be measured accurately, results were expressed as the amount of P_i per milligram of protein in each sample.

Measurements of Na⁺ and Ca²⁺ in Epididymal Fluids Using Ion-Selective Electrodes

Ion-selective microelectrodes were pulled, coated, and filled with either the sodium ionophore I-cocktail A or the calcium ionophore II cocktail A (Fluka Chemicals, Deisenhofen, Germany) as previously described [17]. The electrode was then backfilled with a solution of 100 mM NaCl and 10 mM Hepes at pH 7.4 for determination of Na⁺ or with 10 mM CaCl₂ and 10 mM Hepes at pH 7.4 for measurement of Ca²⁺. Droplets of standards (5 µl) and samples were placed on a Petri dish surrounded by wet tissue paper. Both the reference and the ion-selective microelectrodes were inserted into the drop to measure the potential difference. Signals were recorded with an electrometer (Model FD223, World Precision Instruments, Sarasota, FL). Only electrodes with a linear slope and stable calibration were used. For each sample from one epididymis, a new standard curve was prepared just before collection of the sample (see below). Ion concentrations were calculated from linear regression of the potential response of microelectrodes using Microsoft Origin 6.0 (Microsoft, Redmond, WA).

The mice were anesthetized using Avertin (0.4 ml of a 2.5% [w/v] solution). One epididymis was isolated, and the luminal contents of the cauda epididymidis were collected neat as exudate by retrograde perfusion from the cannulated vas deferens as described above. The perfusion solutions contained Indian ink or trypan blue to mark any mixing with the native luminal contents; were made up in 10 mM Hepes with the target ion at concentrations close to those reported in rats (30 mM Na⁺ and 0.1 mM Ca²⁺ [18]) to reduce any diffusion gradient, if any; and had osmolalities of approximately 400 mmol/kg adjusted with sucrose. Uncontaminated luminal exudate was collected into a positive displacement pipette and immediately measured as described above. Samples from the infertile homozygous KO and the fertile HET control mice were measured alternately. After closing the wound, the animal was allowed to recover for a day or two, and the remaining epididymis was used to measure another electrolyte.

	RESULTS

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RNA Expression of NaP_i Cotransporters Using Gene-Chip Analysis

Comparison of the proximal head of the epididymis from KO and HET animals in four pairs of Affymetrix chips indicated an overexpression of NaP_i-IIb by 9.9 ± 4.0-fold (mean ± SD) in the KO mice. On the other hand, no difference was observed in the corpus region, and expression was nondetectable (registered as absence by the analysis program) in the cauda regions of both genotypes. The corpus region expressed more NaP_i-IIb than the caput region in HET tissues, whereas the same expression levels were detected in the KO tissues, probably because of overexpression in the proximal segment.

Of the other sodium-inorganic phosphate cotransporters analyzed using the gene chips, the level of NaP_i-I (solute carrier family 17, member 1) expression was nondetectable in any region of either genotype investigated. Expression of NaP_i-IIa (solute carrier family 17, member 2) was present in the most proximal region as well as in the caput and corpus and was only marginally detected in the cauda epididymidis, without any significant differences between the genotypes. In both the caput and corpus regions, expression of NaP_i-IIb was more than 5-fold higher than expression of NaP_i-IIa.

RNA Expression of NaP_i-IIb Using Northern Blot Analysis

Using RNA extracted from the caput region, a single signal band of cDNA, with the expected size 403 bp of the amplicon, was obtained for both genotypes by RT-PCR (Fig. 1). Northern blot analysis of tissues from various regions revealed a strong signal band of 4.3 kilobases (kb; similar to the size of intestinal NaP_i-IIb cloned in mouse), with similar intensities in RNA samples from the caput and corpus regions of both genotypes and from the KO region equivalent to the initial segment of the HET (Fig. 2). However, the HET initial segment and the cauda region of both genotypes showed extremely weak signals. Quantification of signal intensities after normalization against total rRNA of each applied sample confirmed the findings in the gene-chip experiments (Fig. 3). Another strong, but very small, signal band of approximately 0.8 kb was also present in all regions except the cauda.

View larger version (54K): [in this window] [in a new window]   FIG. 1. RT-PCR of NaPi-IIb showing the polynucleotide of the expected size (403 bp) reverse-transcribed and amplified from RNA from the epididymal caput region from the HET (lanes 1, 2, and 5) and KO (lanes 3, 4 and 6) c-ros transgenic mice, the negative controls with the omission of the reverse transcriptase (lanes 2 and 4) or Taq polymerase (lanes 5 and 6), or RNA samples (lane 7)

View larger version (97K): [in this window] [in a new window]   FIG. 2. Northern blot of RNA from different epididymal regions of the HET and KO c-ros mice probed for NaPi-IIb expression. Equal loading of RNA for each sample was confirmed by the equal intensity of the 28S rRNA bands on the same blot. Signal bands at 4.3 and 0.8 kb are obvious and show regional as well as genotype differences (see Fig. 3)

View larger version (32K): [in this window] [in a new window]   FIG. 3. Comparison of the level of NaPi-IIb mRNA expression in different epididymal regions of the HET and KO c-ros mice by quantification of the 4.3-kb band in the Northern blot with the signal intensity from each tissue normalized against the intensities of the 28S and 18S rRNA signals

Protein Expression of NaP_i-IIb Using Western Blot Analysis

The NaP_i-IIb antibody recognized two protein bands that were absent from the negative controls (Fig. 4), one in the size of 80 kDa (as expected from the amino acid sequence) and a 67-kDa band. Despite some variability between experiments, probably because of the lack of clear, three-dimensional demarcation for dividing the regions during tissue preparation, a general trend was observed of strongest expression in the corpus region; very weak, if any, expression in the cauda of both genotypes; and higher expression in the KO compared to the HET tissues in the most proximal epididymal region (n = 7) (Fig. 5).

View larger version (50K): [in this window] [in a new window]   FIG. 4. Two Western blots showing protein expression of NaPi-IIb in different epididymal regions of the HET and KO c-ros mice. Specificity of the 80-kDa (band 1) and 67-kDa (band 2) proteins was confirmed by negative controls using primary antibodies adsorbed by the antigenic peptide or using normal rabbit IgG to replace the primary antibodies. Band 1 is stronger in both normal-staining blots (left), whereas band 2 shows variation

View larger version (31K): [in this window] [in a new window]   FIG. 5. Comparison of the level of NaPi-IIb protein expression in different epididymal regions of the HET and KO c-ros mice by quantification of the 80- and 67-kDa band intensities in Western blots, expressing the results for each region in each blot as the ratio of KO to HET values. The dashed line at a relative signal intensity of 1 represents equal levels of expression between genotypes. The histograms represent mean ± SEM (n = 7)

Localization of NaP_i-IIb Protein in the Epididymis

In the HET epididymis, no immunostaining was observed in the initial segment. The protein was localized on the brush border of the epithelium in the more distal regions up to the cauda, from which it was absent. Staining in the lumen was apparently nonspecific, because it was also present after antibody adsorption. In the KO tissues, staining was obvious even in the most proximal region, where the epithelium had not differentiated into the tall columnar cells as in the HET initial segment (Fig. 6). No apparent difference was found between genotypes in the more distal regions. In both genotypes, the efferent ducts showed specific positive staining in the apical membrane of the ciliated cells and in some cilia (micrograph not shown).

View larger version (121K): [in this window] [in a new window]   FIG. 6. Immunohistochemical localization of NaPi-IIb protein specifically on the brush border, showing its absence from the initial segment (IS in a) and cauda epididymidis (c) of the fertile c-ros HET mice and its specific staining in the brush border of the epithelium in the caput (Cap in a) and corpus regions (b). In the KO mice, it is present in the corpus (not shown), caput (Cap in d), and the proximal region (‘IS’ in d) equivalent in gross anatomy to the HET initial segment (note red staining of the brush border of ‘IS’ tubules). Negative control using adsorbed antibodies (e) on KO caput tubules shows the nonspecific staining of the lumen and interstitium, and the lack of specific staining of the brush border. Bar = 40 µm

Levels of P_i in Cauda Epididymidal Fluid

Luminal fluids flushed out of the cauda epididymidal tubules contained 1.14 ± 0.13 mmol (mean ± SEM) of P_i per 1 g of protein (n = 17) in the HET and 0.83 ± 0.05 mmol/g protein in the KO tissues (n = 16), which showed a decrease of 27% (P = 0.037).

Concentrations of Na⁺ and Ca²⁺ in Cauda Epididymidal Fluids

Both the HET and KO animals showed similar concentrations of Na⁺ (mean ± SEM: 26.3 ± 2.4 and 26.8 ± 2.6 mM, respectively; n = 8 and 7, respectively) and Ca²⁺ (30 ± 5 and 35 ± 3 µM, respectively; n = 8 for both genotypes).

	DISCUSSION

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Of the two isoforms of epithelial NaP_i-II cotransporter, NaP_i-IIb was found to be highly expressed in the mouse epididymis, several-fold higher than the other isoform, NaP_i-IIa, which was considered specific to renal tubules. Thus, the present report adds the epididymis to the list of mammalian tissues expressing NaP_i-IIb, including the intestine, lung, trachea, salivary and mammary glands, pancreas, and prostate [10, 17]. The protein was localized to the apical membrane of the efferent ducts and the brush border of the epididymal epithelium, as reported for the intestine [19]. Interestingly, this expression along the posttesticular duct in the adult animal was interrupted at the initial segment, the most proximal part of the epididymal tubule that is differentiated only before puberty, when spermatozoa first move into the excurrent duct. Developmental down-regulation of NaP_i-II from birth to adulthood is observed in both the intestine [20] and the kidney [21] of rats. In the c-ros KO mice, which lack the differentiated initial segment and are infertile [2], no interruption was found in the expression of this gene or protein in this part of the epididymis, with continuous presence from the efferent ducts to the adjacent epididymal tubule. This lack of a region normally not expressing NaP_i-IIb could explain the higher expression at both the protein and gene levels detected by comparing the equivalent gross anatomical segment in the control animals by gene chips and by Northern and Western blot analyses.

The lack of NaP_i-IIb in the initial epididymal segment of c-ros HET mice more likely reflects down-regulation by factors present in the differentiated epithelium than it does a direct down-regulation by c-ros, because NaP_i-IIb was also absent from the cauda, where c-ros is not expressed [2]. Factors involved in the documented developmental down-regulation of NaP_i-II discussed above are unclear. Epidermal growth factor (EGF) administration in developing rats decreases NaP_i-II at the protein level in kidney tubules [22], presumably via inhibition of the gene promoter [23]. Both EGF and EGF receptor are expressed in the epididymis [24, 25]. Another candidate is vitamin D, which stimulates NaP_i-IIb protein expression [26] as well as increases its mRNA in intestinal epithelium [20]. High amounts of vitamin D are known to be present in the epididymis from the detection of its metabolites [27], and vitamin D-binding sites are demonstrated in the epithelium of the caput epididymides [28]. Any differences of these candidate genes or proteins between the c-ros HET and KO mice are unknown.

Data regarding NaP_i-IIb gene expression obtained using the gene arrays and Northern blot analysis were in agreement. The transcript of 4.3 kb was similar in size to those reported in the literature (4 kb in the mouse intestine [9] and 5.0 kb in human tissues [19]). However, another small transcript of 0.8 kb was also detected in abundance in the proximal epididymal regions but only weakly in the corpus and not at all in the cauda regions. This transcript could be generated by alternative splicing. However, any translation into a functional protein is doubtful, because no specific, low-molecular-size protein band was detected in Western blot analyses using the antibody raised against peptide near the C-terminus. On the other hand, the two specific bands of 80 and 67 kDa were smaller than the 108-kDa protein in the adult mouse intestine [9, 29] and lung [30] but were similar to the major band of 78 kDa found in the intestine of prepubertal rats. Interestingly, the extent of glycosylation of the intestinal protein is age dependent, such that an 88-kDa band is expressed in prepubertal mice instead of the 110-kDa band in adults [29], whereas a size of M_r 78 can be deduced from the mRNA sequence [9]. In the epididymis, the 80-kDa molecule could differ from the intestinal protein in glycosylation and likely is the functional isoform, whereas the 67-kDa protein might be a product of posttranslational processing. On the other hand, such differences between tissues as a result of different methods of protein extraction and treatment for Western blot analysis cannot be ruled out.

The concentration of P_i in the luminal fluid from the distal end of the epididymis is very high in the two species studied (16 mM in rats [11] and 24 mM in humans [12]). The present measurement in fertile mice would be equivalent to approximately 18–40 mM, assuming a dilution factor of approximately 75 during sample collection (see Materials and Methods), or a protein concentration of 35 mg/ml of neat luminal fluid (values from other rodents [16, 31]). The level in infertile c-ros KO mice was significantly reduced by 27% (equivalent to 5–11 mM) assuming no change in the protein concentration. However, whether this is a result of the abnormal patterns of gene and protein expression is uncertain. Some degree of P_i reabsorption along the rat epididymis is indicated by the concentrations of P_i measured in the caput, corpus, and cauda regions and the extent of concentration of luminal contents by water reabsorption along the tubule length, as estimated either from the increases in sperm number [32] or in spermatocrit values [11]. The very high level of P_i is compatible with the very low concentration of Ca²⁺ measured in the fluid, suggesting the importance of tight control of both P_i and Ca²⁺ transport in the epididymis to avoid crystallization of calcium phosphate, which may block the passage of sperm. Nevertheless, despite a difference in the P_i concentrations, no difference was observed in the Ca²⁺ concentrations between the fertile and infertile mice.

The physiological implication of a lower P_i concentration in the epididymal lumen of infertile KO mice is unclear, and the site of this decrease remains undefined. High P_i concentrations may be required for the sperm maturation processes taking place in the caput and corpus regions and for the maintenance of the stored spermatozoa in the cauda segment, where NaP_i-IIb was no longer expressed. It may be essential for the development of sperm function that no phosphate reabsorption should occur in the initial segment, which is missing in the KO mice. If the presently measured 27% (estimated to be 5–11 mM) decrease were to occur in this proximal region, it could have crucial consequences for the maturation of testicular spermatozoa coming into the epididymis, because only 6.4 mM P_i is present in the fluid of the proximal caput epididymides of rats (40% of the concentration in caudal fluid [11]).

Because the coupling ratio of NaP_i-II is 3 Na⁺ to 1 P_i [10], it is possible that NaP_i-IIb is also involved in Na⁺ reabsorption. In this respect, renal NaP_i-II is markedly up-regulated when one of the major Na⁺-transporter genes, either the Na⁺-H⁺ exchanger NHE₃ or the Na⁺-Cl^- cotransporter NCC, is nullified [13], and the upregulation was interpreted as one of the compensatory mechanisms. The epididymal epithelium is very active in sodium reabsorption (for review, see [33]), with luminal concentrations decreasing from greater than 100 mM to approximately 30 mM along the entire length of the epididymal tubule [31]. However, despite a decrease in the concentration of P_i, no difference was detectable in the concentration of Na⁺ present in the cauda epididymidal fluid, which was at levels as low as those reported for other species. Therefore, NaP_i-IIb is unlikely to be involved in Na⁺ reabsorption in the epididymis.

In conclusion, the present work established and quantified the regional expression profiles of epididymal NaP_i-IIb and differences between the fertile and infertile genotypes. High expression of NaP_i-IIb was found in the epithelial brush border in regions where sperm maturation occurs, except in the initial segment. In the infertile c-ros KO mouse, the cotransporter was already highly expressed at both mRNA and protein levels in this most proximal region, which does not undergo the normal differentiation at puberty. The resultant lower contents of P_i in the epididymal luminal fluid, without changes in the Na⁺ or Ca²⁺ concentrations, may have implications in the normal maturation of spermatozoa into functional, potent cells.

	ACKNOWLEDGMENTS

 
The authors thank Barbara Hellenkemper and Körber Jolanta for technical assistance, genotyping, and colony maintenance of the transgenic mice and Martin Heuermann and Gunter Stelke for animal care. We appreciate the input of Professor H. Funke, Bianca Foppe, and Sandra Engels from the Integrated Functional Genomics Centre of Münster University for assistance in the gene-chip experiments. We also thank Professor Eberhard Nieschlag from the Institute of Reproductive Medicine for his encouragement of our work.

	FOOTNOTES

 
¹ Supported by the Deutsche Forschungsgemeinschaft, grant number FOR197/3-1, "The male gamete: production, maturation, function," and by the Rockefeller and Ernst Schering Research Foundations' AMPPA Project.

² Correspondence: Ching-Hei Yeung, Institute of Reproductive Medicine, Domagkstrasse 11, Münster, D-48129 Germany. FAX: 49 251 8356093; yeung{at}uni-muenster.de

³ Current address: Schering AG, 13342 Berlin, Germany

Received: 9 April 2003.

First decision: 7 May 2003.

Accepted: 14 May 2003.

	REFERENCES

TOP ABSTRACT INTRODUCTION MATERALS AND METHODS RESULTS DISCUSSION REFERENCES

 

1. Cooper TG. Epididymis. In: Neill JD, Knobil E (eds.), Encyclopedia of Reproduction. New York: Academic Press; 1998:1–17
2. Sonnenberg-Riethmacher E, Walter B, Riethmacher D, Gödecke S, Birchmeier C. The c-ros tyrosine kinase receptor controls regionalization and differentiation of epithelial cells in the epididymis. Gene Dev 1996 10:1184-1193[Abstract/Free Full Text]
3. Yeung CH, Wagenfeld A, Nieschlag E, Cooper TG. The cause of infertility of male c-ros tyrosine kinase receptor knockout mice. Biol Reprod 2000 63:612-618[Abstract/Free Full Text]
4. Yeung CH, Sonnenberg-Riethmacher E, Cooper TG. Infertile spermatozoa of c-ros tyrosine kinase receptor knockout mice show flagellar angulation and maturational defects in cell volume regulatory mechanisms. Biol Reprod 1999 61:1062-1069[Abstract/Free Full Text]
5. Yeung CH, Anapolski M, Sipilä P, Wagenfeld A, Poutanen M, Huhtaniemi I, Nieschlag E, Cooper TG. Sperm volume regulation—maturational changes in fertile and infertile transgenic mice and association with kinematics and tail angulation. Biol Reprod 2002 67:269-275[Abstract/Free Full Text]
6. Yeung CH, Sonnenberg-Riethmacher E, Cooper TG. Receptor tyrosine kinase c-ros knockout mice as a model for the study of epididymal regulation of sperm function. J Reprod Fertil Suppl 1998 53:137-147[Medline]
7. Wagenfeld A, Yeung CH, Lehnert W, Nieschlag E, Cooper TG. Lack of glutamate transporter EAAC1 in the epididymis of infertile c-ros receptor tyrosine-kinase deficient mice. J Androl 2002 23:772-782[Abstract/Free Full Text]
8. Yeung CH, Anapolski M, Cooper TG. Cell volume regulation of mammalian spermatozoa. In: Van de Horst G, Franken D, Bornman R, De Jager T, Dyer S (eds.), Proceedings of 9th International Symposium on Spermatology. Bologna: Monduzzi Editore; 2002:167–172.
9. Hilfiker H, Hattenhauer O, Traebert M, Forster I, Murer H, Biber J. Characterization of a murine type II sodium-phosphate cotransporter expressed in mammalian small intestine. Proc Natl Acad Sci U S A 1998 95:14564-14569[Abstract/Free Full Text]
10. Werner A, Kinne RK. Evolution of the Na-P_i cotransport systems. Am J Physiol Regul Integr Comp Physiol 2001 280:R301-R312[Abstract/Free Full Text]
11. Hinton BT, Setchell BP. Concentrations of glycerophosphocholine, phosphocholine and free inorganic phosphate in the luminal fluid of the rat testis and epididymis. J Reprod Fertil 1980 58:401-406[Abstract/Free Full Text]
12. Hinton BT, Pryor JP, Hirsh AV, Setchell BP. The concentration of some inorganic ions and organic compounds in the luminal fluid of the human ductus deferens. Int J Androl 1981 4:457-461[Medline]
13. Brooks HL, Sorensen AM, Terris J, Schultheis PJ, Lorenz JN, Shull GE, Knepper MA. Profiling of renal tubule Na⁺ transporter abundance in NHE³ and NCC null mice using targeted proteomics. J Physiol 2001 530:359-366[Abstract/Free Full Text]
14. Sonnenberg E, Gödecke A, Walter B, Bladt F, Birchmeier C. Transient and locally restricted expression of the ros1 proto-oncogene during mouse development. EMBO J 1991 10:3693-3702[Medline]
15. Xu YX, Wagenfeld A, Yeung CH, Lehnert W, Nieschlag E, Cooper TG. Expression and location of the taurine transporter in the epididymis of infertile c-ros receptor tyrosine kinase-deficient and fertile heterozygous mice. Mol Reprod Develop 2003 64:144-151[CrossRef][Medline]
16. Back DJ, Shenton JC. A comparison of the composition of epididymal plasma from the cauda epididymides of the rat, hamster and guinea pig. Experientia 1975 31:464-465[CrossRef][Medline]
17. Wagner CA, Friedrich B, Setiawan I, Lang F, Broer S. The use of Xenopus laevis oocytes for the functional characterization of heterologously expressed membrane proteins. Cell Physiol Biochem 2000 10:1-12[Medline]
18. Levine N, Marsh DJ. Micropuncture studies of the electrochemical aspects of fluid and electrolyte transport in individual seminiferous tubules, the epididymis and the vas deferens in rats. J Physiol 1971 213:557-570[Abstract/Free Full Text]
19. Xu H, Bai L, Collins JF, Ghishan FK. Molecular cloning, functional characterization, tissue distribution, and chromosomal localization of a human, small intestinal sodium-phosphate (Na⁺-P_i) transporter (SLC34A2). Genomics 1999 62:281-284[CrossRef][Medline]
20. Xu H, Bai L, Collins JF, Ghishan FK. Age-dependent regulation of rat intestinal type IIb sodium-phosphate cotransporter by 1,25-(OH)₂ vitamin D₃. Am J Physiol Cell Physiol 2002 282:C487-C493[Abstract/Free Full Text]
21. Woda C, Mulroney SE, Halaihel N, Sun L, Wilson PV, Levi M, Haramati A. Renal tubular sites of increased phosphate transport and NaP_i-2 expression in the juvenile rat. Am J Physiol Regul Integr Comp Physiol 2001 280:R1524-R1533[Abstract/Free Full Text]
22. Arar M, Zajicek HK, Elshihabi I, Levi M. Epidermal growth factor inhibits Na-P_i cotransport in weaned and suckling rats. Am J Physiol 1999 276:F72-F78
23. Xu H, Collins JF, Bai L, Kiela PR, Lynch RM, Ghishan FK. Epidermal growth factor regulation of rat NHE₂ gene expression. Am J Physiol Cell Physiol 2001 281:C504-C513[Abstract/Free Full Text]
24. Cain MP, Kramer SA, Tindall DJ, Husmann DA. Alterations in maternal epidermal growth factor (EGF) effect testicular descent and epididymal development. Urology 1994 43:375-378[CrossRef][Medline]
25. Radhakrishnan B, Suarez-Quian CA. Characterization of epidermal growth factor receptor in testis, epididymis and vas deferens of nonhuman primates. J Reprod Fertil 1992 96:13-23[Abstract/Free Full Text]
26. Hattenhauer O, Traebert M, Murer H, Biber J. Regulation of small intestinal Na-P_i type IIb cotransporter by dietary phosphate intake. Am J Physiol 1999 277:G756-G762
27. Kidroni G, Har-Nir R, Menezel J, Frutkoff IW, Palti Z, Ron M. Vitamin D₃ metabolites in rat epididymis: high 24,25-dihydroxy vitamin D₃ levels in the cauda region. Biochem Biophys Res Commun 1983 113:982-989[CrossRef][Medline]
28. Schleicher G, Privette TH, Stumpf WE. Distribution of soltriol [1,25(OH)₂-vitamin D₃] binding sites in male sex organs of the mouse: an autoradiographic study. J Histochem Cytochem 1989 37:1083-1086[Abstract]
29. Arima K, Hines ER, Kiela PR, Drees JB, Collins JF, Ghishan FK. Glucocorticoid regulation and glycosylation of mouse intestinal type IIb Na-P_i cotransporter during ontogeny. Am J Physiol 2002 283:G426-G434
30. Traebert M, Hattenhauer O, Murer H, Kaissling B, Biber J. Expression of type II Na-P_i cotransporter in alveolar type II cells. Am J Physiol 1999 277:L868-L873
31. Cooper TG. The Epididymis, Sperm Maturation and Fertilisation. Berlin: Springer-Verlag; 1986
32. Turner TT, Cesarini DM. The ability of the rat epididymis to concentrate spermatozoa. Responsiveness to aldosterone. J Androl 1983 4:197-202[Abstract/Free Full Text]
33. Wong PYD, Gong XD, Leung GPH, Cheuk BLY. Formation of the epididymal fluid microenvironment. In: Robaire B, Hinton BT (eds.), The Epididymis. From Molecules to Clinical Practice. New York: Kluwer Academic/Plenum Publishers; 2002:119–130

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