©1995 by The American Society for Biochemistry and Molecular Biology, Inc.
Expression and Function of Bicarbonate/Chloride Exchangers in the Preimplantation Mouse Embryo (*)

(Received for publication, May 4, 1995; and in revised form, July 27, 1995)

Yuyuan Zhao (1)(§)(¶) Patrick J-P. Chauvet (1)(§)(**) Seth L. Alper (3)(§§) Jay M. Baltz (1) (2)(¶¶)

From the  (1)Loeb Medical Research Institute, Hormones, Growth and Development Unit, Ottawa Civic Hospital and the (2)Departments of Obstetrics and Gynecology, Reproductive Biology Unit, and Physiology, University of Ottawa, Ottawa, Ontario K1Y 4E9 and the (3)Molecular Medicine and Renal Units, Beth Israel Hospital and Departments of Cell Biology and Medicine, Harvard Medical School, Boston, Massachusetts 02215

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

Bicarbonate/chloride (HCO(3)/Cl) exchangers regulate intracellular pH in the alkaline range. Previously, it has been shown that mouse embryos at the two-cell stage exhibit this activity, but that the otherwise ubiquitous mechanisms for regulating intracellular pH in the acid-to-neutral range are undetectable. We have examined mouse embryos during preimplantation development (one-cell zygote through blastocyst) to determine whether HCO(3)/Cl exchange activity exists at all stages, whether it is necessary for preimplantation development, and whether messenger RNAs from the known HCO(3)/Cl exchanger genes are expressed. We have found that all stages of preimplantation embryo have detectable HCO(3)/Cl exchange activity. In addition, inhibition of this activity with the stilbene anion exchange inhibitor DIDS (4,4`-diisothiocyanostilbene-2,2`-disulfonic acid) disrupts intracellular pH homeostasis and markedly inhibits embryo development from the two-cell stage to blastocysts in culture under conditions of moderately high external pH. Finally, mRNA encoding two members of the band 3-related AE anion exchanger gene family are expressed in preimplantation embryos.


INTRODUCTION

The two-cell stage mouse embryo has been shown to exhibit HCO(3)/Cl exchange activity which mediates recovery from intracellular alkalosis(1) . Biochemically, this activity is much like HCO(3)/Cl exchange activities found in many cultured mammalian cells: it is inhibitable by the stilbene drug DIDS, (^1)is active above about pH 7.2 and has a K for external Cl in the millimolar range(1) . Surprisingly, there was no detectable corresponding activity of mechanisms to correct deviations of pH in the acid direction, such as the otherwise ubiquitous Na/H antiporter (2) or the Na,HCO(3)/Cl exchanger(3) . Similarly, the unfertilized mouse egg has been reported to lack Na/H antiport activity(4) . Thus, HCO(3)/Cl exchange appears to be the sole pH regulatory mechanism in the early embryo (at least at the two-cell stage).

Three genes encoding HCO(3)/Cl exchangers have been identified in mammals(5) . All are related and are homologs of the erythroid anion exchanger, band 3, which functions as both a HCO(3)/Cl exchanger and a membrane anchor of the cytoskeleton in erythrocytes. These homologs are designated AE1, AE2, and AE3 (``AE'' for ``anion exchanger''). The AE1 gene encodes at least two alternate polypeptides, erythroid band 3(6) , and an N terminally truncated kidney-specific form (7, 8) apparently active in renal acid secretion (9) . The AE2 gene encodes at least one polypeptide, which is widely distributed among various tissues and cultured cell lines(10, 11) where it may mediate pH regulation(12, 13) , and/or volume regulation(14) . The AE3 gene encodes at least two alternate transmembrane polypeptides with differing N termini. One was first cloned from brain and is termed the ``brain'' isoform(11, 15, 16) , while the other was cloned from heart and is termed the ``cardiac'' isoform(16, 17) . In addition, alternatively spliced mRNA encoding a polypeptide lacking the transmembrane domain has been described(18) . It is not yet known if all HCO(3)/Cl exchangers are members of the AE family, or if unrelated proteins also serve this function. However, the physiological properties of HCO(3)/Cl exchange in all those cell types where it has been examined resemble those of the proteins of the AE family.

pH regulation by HCO(3)/Cl exchange has similar properties in various nucleated cell types and also when mediated by heterologously expressed AE polypeptides: HCO(3)/Cl exchange is activated above a threshold pH which is usually around 7.1-7.3(1, 19, 20, 21, 22) . This threshold ``set point'' can be altered by metabolic alteration of the cell(12, 22) . The activity is inhibited by stilbene drugs such as DIDS, requires HCO(3) in the cell, and requires an inwardly directed Cl gradient. HCO(3) and Cl compete for the same transport sites, and the apparent K for both anions is similar (generally in the range of 1-10 mM; 1, 12, 26).

While HCO(3)/Cl exchange activity has been demonstrated in the two-cell mouse embryo, neither the molecular basis of this HCO(3)/Cl exchange, nor a requirement for HCO(3)/Cl exchange activity in early development has been described. In addition, there has been no information available on the presence or absence of HCO(3)/Cl exchange activity in other stages of preimplantation embryo. The studies presented here address these questions.


MATERIALS AND METHODS

Embryos

Embryos were obtained from superovulated (intraperitoneal injections of 5 IU PMSG followed 48 h later by 5 IU hCG, Sigma) CF1 female mice mated with BDF males (Charles River, Canada). One-cell stage embryos, two-cell stage embryos, morulae, and blastocysts were obtained 22-24, 44-48, 70-72, and 94-96 h post-hCG, respectively. One- and two-cell stage embryos were obtained by flushing excised oviducts with KFHM medium (described below), morulae were obtained by similarly flushing excised oviduct-uterus complexes, and blastocysts were obtained by flushing excised oviduct-uterine horn complexes or uterine horns alone. The flushed embryos were collected and washed three times in KFHM using mouth-operated, flame-pulled glass pipettes(23) .

Media

KSOM embryo culture medium (24) contains (in mM except as noted) 95 NaCl, 2.5 KCl, 0.35 KH(2)PO(4), 0.2 MgSO(4), 10 sodium-lactate, 0.2 glucose, 25 NaHCO(3), 1.7 CaCl(2), 1.0 glutamine, 0.01 tetrasodium EDTA, 60 µg/ml K penicillin G, 44 µg/ml streptomycin SO(4), and 1.0 mg/ml bovine serum albumin (all from Sigma, embryo culture tested or tissue culture tested grades). The pH of KSOM as a function of CO(2) concentration was determined with a Corning (Corning, NY) combination pH electrode with temperature compensator and Corning pH meter (model 350 ion analyzer) while bubbling the medium with a defined CO(2)/air mixture (using a Cole-Parmer, Niles IL, gas proportioner with N042 flow tubes). The measured equilibrium pH of KSOM at 5.0, 2.5, 2.0, 1.7, 1.5, 0.8, and 0.4% CO(2) is 7.35, 7.59, 7.77, 7.85, 7.94, 8.10, and 8.32, respectively. KFHM medium(24) , wherein 21 mM of the NaHCO(3) in KSOM is replaced by equimolar HEPES (pH adjusted with NaOH to 7.4 at 37 °C), was used for obtaining and handling the embryos.

Embryo Culture in Varying CO(2) Concentrations with and without the Anion Exchange Inhibitor DIDS

Two-cell stage embryos were placed into culture at approximately 46-48 h post-hCG. They were cultured in 50-µl drops of KSOM medium in standard microdrop cultures (23) under medium-equilibrated mineral oil (Sigma, embryo-tested grade) in Falcon tissue culture dishes, in a CO(2) incubator (VWR, South Plainfield, NJ, model 35908-100) at 37 °C and 100% humidity. Drops containing the anion exchange inhibitor DIDS (100 µM, Molecular Probes, Eugene, OR) were prepared by adding fresh 100 mM stock in dimethyl sulfoxide to CO(2)-equilibrated KSOM; control drops had the same amount of dimethyl sulfoxide alone (0.1%) added. DIDS did not significantly partition into the oil phase overlying the drops; we found that >90% of the DIDS (measured by absorbance at 340 nm) remained after vigorous vortexing with a 10-fold excess of oil. Groups of two-cell embryos (usually 15/group) were placed into culture drops, with the groups evenly divided between DIDS and control cultures, and immediately returned to the CO(2) incubator. Almost all embryos in control cultures reached the expanded blastocyst stage by 68-70 h; embryos were considered to be expanded blastocysts if they had a large fluid-filled blastocoel cavity and a distinct inner cell mass. Embryos were cultured in this way at 0.4, 0.8, 1.5, 1.7, 2.0, and 5% CO(2).

The results of these experiments were expressed as the number of embryos reaching the expanded blastocyst stage after 68-70 h of culture. There were three or four replicates at each CO(2) concentration (except for 0.4%, where there were two). These replicates were tested for homogeneity and found to be not significantly different (all p > 0.05 by Fisher's exact test, except for one anomalous replicate at 1.5% CO(2), control, which was nonetheless included). The replicates were therefore pooled for further analysis. The data were analyzed by logistic regression analysis, which allows estimates of the effects of each individual treatment variable as well as any interactions between them. The logistic regression parameters were calculated by exact calculation, rather than using asymptotic methods, since this allows for sparse data sets and data sets with numerous responses near 0 and 100%.

Intracellular pH (pH(i)) Measurements

Measurements of embryo pH(i) were made using an intracellularly loaded pH-sensitive fluorescent probe, by ratiometric imaging with a quantitative imaging fluorescence videomicroscopy system built around a Zeiss Axiovert inverted epifluorescence microscope. Fluorescence excitation was via a grating-type monochrometer (Photon Technologies International, New Brunswick, NJ) with an electronic shutter (UniBlitz, Vincent Associates, Rochester, NY). The image was detected with a solid-state video camera (CCD72, Dage-MTI, Michigan City, IN) fitted with a Geniisys image intensifier (DAGE-MTI) and a tunable imaging monochrometer (VariSpec model VISI5, Cambridge Research Instruments, Cambridge, MA). All these are controlled by Isee and dsp/os software and imaging hardware (Inovision, Inc., Durham, NC) running on a Silicon Graphics Indigo2 (R4400, Extreme Graphics) Unix workstation (Silicon Graphics, Mountain View, CA). The pH(i) measurements were made using SNARF-1, a pH-sensitive fluorophore, loaded into embryos using SNARF-1-AM (5 µM in KFHM for 30 min at 37 °C; Molecular Probes, Eugene, OR). Excitation was 535 nm; ratiometric measurements were obtained using emission wavelengths of 640 and 600 nm. Spectra (570-670 nm) obtained in situ from embryos clamped at various pH(i) showed that 600 nm was an isosbestic point, while 640 was maximally pH-sensitive. The ratio of intensity at 640 divided by that at 600 was calculated on a pixel-by-pixel basis using the Inovision Isee software, and the mean ratio for each embryo or cell (in two-cell embryos) recorded. The ratio was linearly related to pH in the range of 6.9-8.0; ratios were converted to pH by clamping pH(i) to the extracellular values using nigericin (10 µg/ml, Sigma) and valinomycin (5 µg/ml, Sigma) in 100 mM K solution(2, 25) .

pH(i) Measurements of Embryos under Culture Conditions

To assess the effect of DIDS on the pH(i) of cultured embryos, pH(i) of two-cell stage embryos was measured under conditions that were as close to normal culture conditions as possible: SNARF-1-loaded embryos were placed in pre-equilibrated microdrop culture dishes containing either KSOM or KSOM + 100 µM DIDS, as for culture, and placed into the incubator with an atmosphere of 5.0, 1.7, or 0.8% CO(2). After 3-5 h in culture, five pairs of images (640 and 600 nm, 32 video frames averaged) of the embryos in each culture, and then two background images away from the embryos were immediately taken. Ratio images were calculated after background subtraction and the mean ratio of each embryo cell determined (as described above).

Four to six replicates (36-74 embryos total/treatment) at each CO(2) concentration with and without DIDS were used. The data from identical conditions were pooled and normal distribution confirmed by normal probability plots. To determine if there was a significant effect of CO(2) on pH(i), the data were analyzed by two separate ANOVAs, one treating the data with [DIDS] = 0 at all three CO(2) levels, and the other treating the data with [DIDS] = 100 µM at all three CO(2) levels. These tests determine if pH(i) depends on CO(2) level in control medium or in DIDS-containing medium. To determine if DIDS had a significant effect on pH(i), the data were analyzed by an exact Wilcoxon Rank Sum test. The data were treated as comprising two groups (DIDS and control) stratified by CO(2) (i.e. treating it as a confounding variable). This test determines if pH(i) depends on the presence or absence of DIDS overall.

Detection of Functional HCO(3)/Cl Exchangers in Embryos

HCO(3)/Cl exchanger can be detected by monitoring pH(i) during replacement of the external medium with one which lacks Cl(3, 19, 26) . The subsequent efflux of Cl through any HCO(3)/Cl exchanger(s) present obliges an import of HCO(3) into the cell, increasing pH(i). The exchanger runs in the reverse direction to that required by its usual physiological role but still effects HCO(3)/Cl exchange. Activity is confirmed by showing that the rise is abolished by DIDS but independent of external Na.

SNARF-1-loaded embryos were placed into a temperature- and atmosphere-controlled chamber (37 °C and 5% CO(2); Biophysica Inc., Baltimore, MD) fitted with a perfusion apparatus (solution changed in <30 s). After monitoring pH(i) for 10 min, the medium (KSOM with 9 mM sodium lactate replaced by NaCl, [Cl] = 110 mM) was replaced by medium that was identical except that Cl was replaced by gluconate and sulfate ([Cl] = 0, nominally); 100 µM DIDS was used to assess inhibition, and Na- and Cl-free medium was used to assess Na dependence (NaCl, sodium lactate, and sodium pyruvate replaced by isosmotic sucrose, remainder of Cl replaced by gluconate, and HCO(3) supplied by choline HCO(3)). Embryos at the one-cell, two-cell, morula, and blastocyst stages were used. Blastocysts were mechanically collapsed by passage through a narrow-bore pipette to allow DIDS access to the blastocoel cavity(27) . Three measurements, with and without DIDS, and two measurements without Na, were carried out at each stage (8-20 embryos/measurement group). The data, expressed as the mean pH(i) of the group of embryos at each time point, were analyzed by determining the initial rate of pH(i) increase after Cl removal, and by determining the maximum net change in pH(i). Initial rate of pH(i) increase was determined by a linear regression performed on the linear portion of the increase, constituting the first seven (one-cell stage) or 10 (other stages) data points (taken at 30-s intervals). The net increase was determined as the difference between the base-line pH(i) just prior to Cl removal, and the peak or plateau pH(i) following Cl removal (both averaged over 5 min). Statistical analysis was performed to determine whether the initial rate of increase and/or net increase were significantly different in the presence or absence of DIDS; this was done by t test (assuming unequal variances) at each stage. The data were also analyzed to determine if the initial rate of increase or net increase in pH(i) changed over development. Initial examination showed that there was no significant difference in either parameter (by t test) between the one- and two-cell stages, nor between the morula and blastocyst stages, so the data for one- and two-cell and for morula and blastocyst were pooled for further analysis. To determine if there was a change over development, t tests (two-tailed, assuming equal variances) were performed to compare initial rates and net changes between the pooled one- and two-cell, and the pooled morula and blastocyst, groups.

Isolation of mRNA and Preparation of cDNA from Embryos

For RNA isolation, the embryos were obtained as described above, and washed eight times through clean drops. The embryos were placed in a ninth drop with micrococcal nuclease (0.006 micromolar units/µl; Sigma) for 15 min at 37 °C, which eliminated false positive signals which otherwise arose from the wash medium. Since micrococcal nuclease is Ca-dependent, it was only active in this step, as subsequent steps were Ca-free. Groups of 50 embryos were placed into 300 µl of lysis buffer (0.5% SDS in TE buffer with 0.02 µg of Escherichia coli, Sigma). The samples were phenol-extracted, and the nucleic acids ethanol-precipitated, pelleted, washed with 70% ethanol, dried on a vacuum concentrator (Speed-Vac), and resuspended in 6 µl water with 1 µl/100 µl RNase inhibitor. The mRNA from the embryos was then reverse transcribed in 20 µl total volume using the Promega RT Kit and oligo(dT) primer.

Polymerase Chain Reaction (PCR) Determination of Anion Exchanger mRNA in Embryos

To detect cDNAs reverse transcribed from anion exchanger mRNAs in embryos, 30 cycles of PCR were performed as described below. In addition, for increased specificity and increased sensitivity in detecting the small amounts of mRNA produced by a few embryos, a ``semi-nested'' PCR protocol was used in which the products of the 30-cycle PCR were diluted 100-fold, and then a second, 20-cycle round of PCR was performed using the same 5` primer, and a 3` primer internal to the first one. Primers, close to the 3` end of the translated regions of each message, were designed for AE1, AE2, and AE3 (Oligo 4.1, National Biosciences, Plymouth, MN) and synthesized (Beckman Oligo 1000). The sources of the mouse anion exchanger cDNA sequences used were, for AE1, (6) ; for AE2, 10; and for AE3, 15. The PCR primers sequences were (shown 5` to 3`): AE1 5`, CTG TTC AAG CCA CCC AAG TA; AE1 3`, TCA CAC AGG CAT GGG CAC TT; AE1 3`-internal, ATC ATC ACC GTC CAG ACA CT; AE2 5`, GTC AAA AAG GTT CGG ACC AT; AE2 3`, TGC CTC TGG ACA GCA GCT AC; AE2 3`-internal, CAC TGG CTC TGC CTC ATT AG; AE3 5`, GGG CGT CAC ATC ACT GTC TG; AE3 3`, AGG CAC ATC CCT GGG TCT GA; AE3 3`-internal, AAA GTT CGG CTC CGC ATC TT.

The Perkin Elmer Cetus PCR kit with Taq DNA polymerase was used with 1 µl of embryo cDNA (equivalent to 2.5 embryos) or diluted 30-cycle product, in 20 µl total volume. The temperature cycle was 93 °C (1 min), 55 °C (1 min), and 72 °C (3 min; or 13 min at end), controlled by a PTC-100 thermocycler (MJ Research, Watertown, MA). The products were analyzed on agarose gels (3:1 NuSieve:Seakem, FMC) and visualized with ethidium bromide. The predicted product sizes from cDNA were: for the 5`,3` pair (30-cycle PCR), AE1, 303; AE2, 280; AE3, 449; for the semi-nested PCR (5`, 3`-internal pair), AE1, 237; AE2, 210; AE3, 301.

These primers flank at least one intron in each genomic sequence so that any product due to contaminating genomic DNA would be identifiably larger than that arising from cDNA, and embryo samples in which reverse transcriptase was omitted were all negative (not shown). Thus, any detected bands must arise from mRNA. To control for the possibility that our semi-nested PCR protocol was too sensitive and was detecting ``leaky transcription'' (see ``Discussion''), we used cDNA derived from tissues known not to express significant levels of a given AE message. Each negative control tissue was run in parallel with a positive tissue. For AE1, stomach was used as a negative control, and spleen as positive(11) ; for AE3, spleen was used as negative and heart as positive(11) . Unfortunately, there is no tissue which has been definitively shown to be negative for AE2, and thus no obvious negative control(10, 11) ; stomach, brain, heart, and kidney were all positive. Neither of the negative control tissues showed any detectable band of the expected size, while all positive controls were clearly positive (data not shown). Thus, any mRNAs detected by our PCR methods are unlikely to result from over-amplification and detection of non-physiological (``leaky'') transcription.

Restriction Digest Confirmation of PCR Products

The identities of (semi-nested) PCR products were confirmed by restriction analysis. The predicted AE1 product should yield BglI fragments of 137 and 100; the predicted AE2 should yield RsaI fragments of 146 and 64; the predicted AE3 product should yield HincII fragments of 170 and 131. To obtain enough PCR product for restriction enzyme digestion, semi-nested PCR reactions were carried out as described above, except that the second round (using the 5` and 3`-internal primers) was carried out for 30 rather than 20 cycles and was done at a 5-fold larger scale (100 µl total). The resultant products were then ethanol precipitated and resuspended in the appropriate restriction buffer as supplied by the manufacturer and digested according to the manufacturer's instructions.

Statistics

ANOVAs, t tests, and linear regressions were performed using Microsoft Excel (Microsoft, Inc.). Normal probability plots were constructed using SigmaPlot for Windows v. 1.0 (Jandel Scientific, San Rafael, CA). Fisher's Exact and Wilcoxon Rank Sum tests were performed with the StatXact software package (Cytel Inc., Cambridge, MA), which allows exact as well as asymptotic calculation of probabilities. Logistic regression analysis was performed with LogXact (Cytel), which fits response data which follows a logistic response; LogXact allows fits to arbitrary models of parameter dependence and exact and asymptotic calculation of the probabilities associated with the terms of these fits and their confidence limits. The Hosmer-Lemeshow test and Deviance test, both indicating goodness of fit in a logistic regression, were also calculated using LogXact.


RESULTS

Effect of Alkaline pH and the Anion Exchange Inhibitor DIDS on Embryos in Culture

Two-cell stage mouse embryos were cultured for 3 days at 37 °C and 5.0, 2.0, 1.7, 1.5, 0.8, or 0.4% CO(2). Fig. 1shows the percentage of two-cell embryos which reached the expanded blastocyst stage by 70 h in culture as a function of CO(2) concentration and medium pH. Lowering CO(2), even as far as 0.4% (pH 8.32), had only a minimal, although statistically significant, effect on the proportion of embryos developing to the blastocyst stage (p = 0.007 by exact calculation of logistic regression parameters on CO(2) dependence using the model: Logit(proportion of blastocysts) = beta(1)[CO(2)] + beta(2), where beta(i) are constants; only a marginally good fit was demonstrated by the Hosmer-Lemeshow test, p = 0.074, and the Deviance test, p = 0.066, indicating weak dependence on CO(2)). Thus, two-cell stage embryos will develop at a fairly high rate (70-80%) to the expanded blastocyst stage even in medium with very high pH.


Figure 1: Development of two-cell mouse embryos to blastocysts as a function of CO(2) concentration with and without the HCO(3)/Cl exchange inhibitor DIDS. Two-cell embryos were cultured for 70 h, and the proportion reaching the expanded blastocyst stage was determined. The CO(2) level was varied, and embryos were cultured in the presence or absence of the HCO(3)/Cl exchange inhibitor DIDS (100 µM). Lowering CO(2) (shown on bottom axis) and therefore raising the pH of the medium (shown on top axis) had little effect in the absence of DIDS (bullet), but in the presence of DIDS (), higher pH was markedly inhibitory. Details of the data and analysis are given in the text.



The inclusion of the anion exchange inhibitor, DIDS (100 µM), in the culture medium with 5% CO(2) (pH 7.35) had no effect on the proportion of embryos developing to blastocysts by 70 h in culture: 98% of the embryos developed to blastocysts in the presence of DIDS, which is not significantly different from the 93% obtained in the absence of DIDS (p = 0.62 by Fisher's exact test). Thus, DIDS alone is non-toxic.

However, at lower CO(2) levels (2.0% down to 0.4%), DIDS greatly inhibited the development of embryos, with fewer than 20% reaching the blastocyst stage at 0.4 and 0.8% as compared to the 70-80% in the absence of DIDS (Fig. 1). To show that the effect of DIDS was significant, and that it depended on an interaction with CO(2), the full data set was analyzed by exact logistic regression analysis. The regression model assumed dependence on DIDS and on an interaction between CO(2) and DIDS (model: Logit(proportion of blastocysts) = beta(1)[DIDS] + beta(2)[DIDS] times [CO(2)] + beta(3); a very good fit was demonstrated by the Hosmer-Lemeshow test, p = 0.88, and Deviance test, p = 0.29). This model was chosen after models in which a [CO(2)] term had been included failed to give an adequate fit by the Hosmer-Lemeshow test, and also failed to converge, indicating that dependence on [CO(2)] alone does not contribute significantly to the overall fit. This analysis showed that both the effect of DIDS and the interaction between DIDS and CO(2) were highly significant (both beta(1) and beta(2) were highly significantly different from zero, p < 10). Therefore, DIDS, but only in conjunction with lowered CO(2) level, significantly decreases overall development.

Intracellular pH (pH(i)) of Two-cell Embryos under Culture Conditions

To see if the inhibition of development which occurs when low [CO(2)] (high external pH) and DIDS are combined was secondary to an increase in intracellular pH, pH(i) of two-cell stage embryos was determined under the same conditions in which they were cultured. Embryos were cultured with or without DIDS, in 5, 1.7, or 0.8% CO(2). Each determination was repeated four to six times, for a total of 36-74 ratio measurements under each condition. Fig. 2shows the results of these measurements. Lowering CO(2) levels in the absence of DIDS had only a small effect on the ratio. However, in the presence of DIDS, the mean ratios were higher at each CO(2) level and had a much steeper dependence on [CO(2)]. Ratios were converted to approximate pH(i) by determining the mean ratios at several different pH(o) values in separate embryos using the nigericin/high K method of equalizing pH(i) and pH(o), yielding the pH(i) values shown on the right axis of Fig. 2. The approximate mean pH(i) values at 5, 1.7, and 0.8% CO(2) were 7.10, 7.15, and 7.24, respectively, in the absence of DIDS and 7.29, 7.52, and 7.57, respectively, in the presence of DIDS. Population distributions of individual embryo pH(i) are indicated by the box plots in Fig. 2.


Figure 2: Intracellular pH of two-cell embryos after 3-5 h in culture as a function of CO(2) concentration with and without the HCO(3)/Cl exchange inhibitor DIDS. Using the intracellular pH-sensitive fluorophore SNARF-1, the fluorescence emission intensity ratio (640-600 nm) and hence intracellular pH (pH) was measured under the same conditions in which embryos were cultured. The presence of the HCO(3)/Cl exchange inhibitor DIDS () resulted in significantly elevated pHrelative to control (bullet). The elevation was much more pronounced at lower CO(2) levels. The vertical axes show the measured fluorescence emission intensity ratio (left) and the calculated pH (right). The small filled symbols represent the mean pH from four to six pooled replicates (36-74 embryos); the box plots superimposed at each point represent the population spread of the data: the center line is the median, while the upper and lower bounds of the box are the 75th and 25th percentiles, respectively, and the whiskers show the 10th and 90th percentiles. See text for experimental details and data analysis.



Analysis of these data was performed in two steps. First, the effect of varying CO(2) alone at constant [DIDS] was tested by ANOVA, treating the [DIDS] = 0 and [DIDS] = 100 µM groups separately. For each group, it was found that varying CO(2) had a highly significant effect on pH(i) (both p < 10). However, the effect was small in the absence of DIDS, and occurred only at 0.8% CO(2), but not at 1.7 or 5% CO(2) (Fig. 2). The second analysis tested the significance of the effect of DIDS and was performed on the entire data set. For this purpose, the data set can be considered to be stratified by CO(2) level, and the effect of CO(2) eliminated by considering it a confounding variable, and so the Wilcoxon Rank-Sum test for stratified data was used. The effect of DIDS was found to be highly significant, with p < 10. Thus, the presence of DIDS in culture raises pH(i) significantly. Pairwise t tests (assuming unequal variances, since all F tests showed significant difference in variances) performed at each of the three CO(2) levels showed highly significant differences in mean pH(i) at each CO(2) (all p < 10). Thus, pH(i) is raised by DIDS even in 5% CO(2); however, the effect is much greater at lower CO(2), with pH(i) being very high at 1.7 and 0.8% CO(2) in the presence of DIDS (Fig. 2).

Presence of Functional HCO(3)/Cl Exchange at Each Stage

HCO(3)/Cl exchange was detected by replacing the medium with Cl-free medium and determining if there was an increase in pH(i) (as described under ``Materials and Methods''). Fig. 3shows the results of these experiments at the one-cell, two-cell, morula, and blastocyst stages. At each stage, switching to Cl-free medium resulted in a marked increase in pH(i); pH(i) then stabilized at a new higher level or peaked and then slowly decreased (as in Fig. 3A). The origin of the decrease is unknown but may be due to passive flux of acid or base equivalents across the membrane(27) . The increase was nearly eliminated by the anion exchange inhibitor DIDS (100 µM) (Fig. 3A). The initial rates of increase (Fig. 3B) in the absence of DIDS are all significantly greater than those with DIDS at the same stage, by one-tailed t tests (p = 0.023, 0.032, 0.004, and 0.021, for one-cell, two-cell, morula, and blastocyst, respectively). The mean maximum net pH(i) increase (Fig. 3C) in the absence of DIDS are also all significantly greater than those with DIDS at the same stage, by one-tailed t tests (p = 0.015, 0.005, 0.008, and 0.009, for one-cell, two-cell, morula, and blastocyst, respectively).


Figure 3: HCO(3)/Cl exchanger activity during preimplantation development. A, plots of pHi versus time in 1-cell, 2-cell, morula, and blastocyst stage embryos monitored before and after switching to Cl-free medium. pH(i) was measured (as described in the text) in embryos in normal Cl medium (bullet) and then the medium was replaced by Cl-free medium (circle), which caused an increase in pH at each stage. The increase was not affected by lack of external Na (middle set of plots) but was completely inhibited by DIDS (100 µM; lowest set of plots). Each trace represents the mean pH in a group of embryos in one representative experiment. Points are separated by 1 min, except immediately following the removal of Cl, where they are separated by 30 s. B, initial rate of pHi increase at each stage. The initial rate of increase of pH upon replacement of the medium with Cl-free medium was determined by linear regression (as described in the text). The bars represent the mean rate (± S.E.) of this increase at each stage. Cross-hatched bars represent the mean initial rates in control medium, bars with horizontal lines represent the rates in the absence of external Na, while the open bars represent the rates in the presence of 100 µM DIDS. See text for data analysis. C, net increase in pH. The net increase in pH from normal medium to its new steady-state value in Cl-free medium is shown for each stage (mean ± S.E.). Cross-hatched bars represent the mean increase in control medium, bars with horizontal lines represent the increase in the absence of external Na, while the open bars represent the increase in the presence of 100 µM DIDS. See text for data analysis.



An increase in pH(i) upon Cl removal could potentially be mediated by either HCO(3)/Cl exchange or Na,HCO(3)/Cl exchange. To ensure that we were detecting HCO(3)/Cl exchange, Cl removal was performed in nominally Na-free medium (Fig. 3). In the absence of external Na, pH(i) still increased upon removal of Cl at each stage. The mean initial rates of increase (Fig. 3B) were not significantly different from the control recoveries at each stage (p = 0.89, 0.15, 0.64, and 0.42, respectively, by two-tailed t test). The mean extents of the increase (Fig. 3C) were also not significantly different from control at any stage (p = 0.75, 0.57, 0.53, and 0.10). Therefore, there was no evidence of significant Na,HCO(3)/Cl exchange activity at any stage tested, indicating that the increase in pH(i) upon Cl removal at each stage demonstrates that there is HCO(3)/Cl exchange activity present at each stage.

To determine whether there was a change in the initial rate of increase of pH(i), or in net increase in pH(i), over the course of preimplantation development, a t test (two-tailed) was performed to test for a significant difference between the pooled results for one- and two-cell stages, and the pooled results for morula and blastocysts (one- and two-cell, and morula and blastocyst stage results were pooled after determining that there was no significant difference in either parameter within pooled stages; see ``Materials and Methods''). Both the initial rate of increase (Fig. 3B) and the net increase (Fig. 3C) decreased significantly from the one- and two-cell stages to the morula and blastocyst stages (p = 0.039 for initial rate and 0.0015 for net increase).

HCO(3)/Cl (Anion) Exchanger mRNAs in Preimplantation Embryos

Embryos at the one-cell, two-cell, morula, and blastocyst stages were examined by RT-PCR for the expression of mRNAs coding for products of the three known HCO(3)/Cl exchanger genes, AE1, AE2, and AE3. Fig. 4shows the results of these RT-PCR assays. After 30 cycles of PCR, AE2 is detectable at the one-cell and blastocyst stages, more faintly at the morula stage, and barely at the two-cell stage (Fig. 4A). Neither AE1 nor AE3 is detected at any stage after 30 cycles. Using the more sensitive semi-nested PCR protocol, both AE2 and AE3 mRNAs were detectable during preimplantation development. AE2 was again found throughout the preimplantation period, with the greatest amount of product at the one-cell and blastocyst stages, consistent with the results obtained with 30-cycle PCR. AE3 was present from the two-cell stage through the blastocyst stage, but was weakly detected in only a minority of samples of one-cell stage embryos (Fig. 4B). In contrast, AE1 PCR products were barely detectable, and only in a minority of samples, at the one-cell and blastocyst stages, and were undetectable at the two-cell or morula stages (even when another 10 cycles of PCR were added; not shown). PCR products corresponding to AE cDNAs were never found in negative control samples consisting of the last wash drop which had contained the embryos (Fig. 4B).


Figure 4: RT-PCR assays for known HCO(3)/Cl exchanger isoform mRNA expression in preimplantation embryos. A, 30- cycle PCR. The lanes are marked as follows: 1 = one-cell embryos; 2 = two-cell embryos, m = morulae; b = blastocysts; all four stages are shown for each of AE1, AE2, and AE3, as marked. Expected sizes of PCR products are marked at right of gel. The unmarked lanes at right and left are phiX-174 HindIII digest markers (sizes shown at left). AE2 products are seen at the one-cell and blastocyst stages, faintly at the morula stage, and are barely visible at the two-cell stage. B, semi-nested PCR. The first two lanes of each gel are positive controls consisting of RT-PCR products of tissues known to express the relevant mRNA (AE1: kidney, spleen; AE2: stomach, kidney; AE3: brain, heart). Embryo lanes are marked as in A. The lanes marked e are PCR products derived from PCRs starting with cDNA from the equivalent of 2.5 embryos; lanes marked w are negative controls consisting of a sample of the drop in which the embryos were washed, treated identically to the embryo samples (i.e. RNA isolation, RT-PCR). Expected sizes of PCR products are marked at right of gels. The unmarked lanes at right and left are markers as described in A.



To ensure that the PCR products visualized were indeed derived from specific AE mRNAs, we used restriction enzymes to cleave the products and show that the fragments generated were of the expected sizes. Fig. 5shows these results: the PCR products from embryos all gave the expected restriction fragments, and therefore arise from the designated AE mRNAs.


Figure 5: Restriction digest confirmation of identity of HCO(3)/Cl exchanger isoform mRNAs. For restriction digests of PCR products, seminested PCR reactions similar to those used to generate the products shown in Fig. 4B were run, except that five times larger reactions were run, 10 additional cycles of PCR were used, and the entire product was used for restriction digest (see ``Materials and Methods''). The PCR products were digested with appropriate restriction enzymes and the sizes of the resulting fragments determined from the gel. The AE isoform is specified at the top. Embryo stages are marked at the top as 1c, 2c, M, and Bl for one-cell, two-cell, morula, and blastocyst, respectively. The restriction enzyme, expected fragment sizes, and size of original PCR product (in parentheses) is indicated under the gel. Marker lanes at right and left are phi X 174 HinfI digest (sizes shown at left).




DISCUSSION

Is HCO(3)/Cl Exchange Present throughout Preimplantation Embryo Development?

The data presented here indicate that HCO(3)/Cl exchange activity persists throughout preimplantation embryo development in the mouse. We have demonstrated the presence of HCO(3)/Cl exchange activity at each stage by showing a pH(i) increase upon removal of Cl from the external medium, which causes Cl efflux from the cell and hence HCO(3) influx through any functional HCO(3)/Cl exchanger (Fig. 3). That this pH(i) rise is due to HCO(3)/Cl exchange is confirmed by the abolition of the increase by DIDS, and its lack of dependence on external Na. HCO(3)/Cl exchange activity, by this measure, is highest at the one- and two-cell stages and decreases significantly by the morula and blastocyst stages. In addition, work in progress in our laboratory (^2)indicates that recovery from an induced intracellular alkalosis is dependent on external Cl and on HCO(3) at each stage of preimplantation embryo, further indicating the presence of functional HCO(3)/Cl exchange throughout preimplantation development.

Is HCO(3)/Cl Exchange Activity Necessary for Preimplantation Development?

Under normal culture conditions (i.e. 5% CO(2), pH 7.35), inhibition of HCO(3)/Cl exchange activity by the anion exchange inhibitor DIDS does not decrease the proportion of two-cell embryos which reach the expanded blastocyst stage by 70 h of culture (Fig. 1), indicating that DIDS (at 100 µM) is not nonspecifically toxic to embryos. DIDS does, however, significantly raise pH(i) under these conditions (Fig. 2). However, when the external pH during culture is raised by lowering [CO(2)], the presence of DIDS has a dramatic effect on embryo development. More than 70% of two-cell embryos develop to blastocysts even in the highest pH used (at [CO(2)] = 0.8 and 0.4%), but this decreases to 10-20% when DIDS and high pH are combined. Furthermore, when embryos are exposed to even moderately alkaline conditions, functional HCO(3)/Cl exchange is necessary for development: at pH 7.8 (2% CO(2)), over 90% of two-cell embryos develop to blastocysts, but this drops to less than 40% in the presence of DIDS. Thus, it appears that HCO(3)/Cl exchange activity is necessary for embryo development in the face of even modest increases in external pH. To our knowledge, while it has been clearly shown that HCO(3)/Cl exchange activity participates in pH(i) regulation and volume regulation in many cell types, this is the first demonstration that HCO(3)/Cl exchange activity is required for viability or development in any tissue or cell.

A rise in pH(i) is the most likely cause of the decreased development observed in low CO(2) when HCO(3)/Cl exchange activity is inhibited. Without DIDS, the mean pH(i) is maintained below 7.2 even when the external pH is well above 8.0. This in itself is indicative of activity of the embryo HCO(3)/Cl exchanger, whose activation threshold is about 7.2(1) . However, in the presence of DIDS, pH(i) is higher at all CO(2) levels tested (Fig. 2). With the exchanger inhibited, mean pH(i) rises to above 7.5, with the pH(i) in individual embryos rising to above 7.8 (the box plots at each point show the population distribution, see figure legend). The greatest pH(i) increases correlate with the most significantly decreased embryo viability, as can be seen from Fig. 1and Fig. 2. Taken together, the data shown in these figures suggest the possibility that the lethal level of pH(i) is about 7.45; the percentages of embryos in each treatment group which fail to develop is approximately equal to the proportion whose pH(i) values are above 7.45 (although a direct correspondence between those embryos with highest pH(i) and those which fail to develop has not been shown).

The results of culture at 5% CO(2) with DIDS indicate that, under normal culture conditions, HCO(3)/Cl exchange activity is not needed for development in vitro. However, it is likely to be necessary for development in vivo. The pH values of oviductal and uterine fluids have not been determined in the mouse, but in other species where this has been measured, the oviductal fluid surrounding embryos has been found to have a high bicarbonate content and high pH, with up to pH 7.7 measured in the rhesus monkey (28) , and 7.8-8.2 in the rabbit (29, and references therein). Thus, while artificial culture conditions may allow embryos to grow in the absence of HCO(3)/Cl exchange activity, it may be continually needed in vivo at least in the portion of preimplantation development that occurs in the oviduct. It is also clear from Fig. 2that pH(i) is affected even at 5% CO(2); this may place a stress on the embryos which would compromise their viability in the face of any additional adverse conditions, even if not lethal by itself.

Are AE Family HCO(3)/Cl Exchangers Present in Preimplantation Embryos?

Our RT-PCR data indicate that AE mRNAs are expressed in preimplantation mouse embryos. AE2 is apparently expressed throughout preimplantation development. It is detectable using mRNA from the equivalent of as few as 2.5 cells after only 30 cycles of PCR and yields a strong signal after semi-nested PCR. AE3 appears to be expressed at least from the two-cell stage onward, as it is detectable with semi-nested PCR (although not after only 30 cycles). In some one-cell samples, a very weak AE3 signal was seen; we believe that this is probably not indicative of functionally important transcription since the signal was extremely weak and was observed in only a minority of the one-cell embryo samples. AE1 mRNA is not expressed at a significant level in the preimplantation embryo, since we detected only a very weak signal in only a minority of samples after seminested PCR (and even then only at the one-cell and blastocyst stages).

RT-PCR is an extremely sensitive technique. In some cases leaky transcription can occur, in which a very few copies of an mRNA are transcribed nonspecifically. These non-physiological transcripts can potentially be detected by RT-PCR if amplification continues for enough cycles. However, the AE2 and AE3 transcripts which we detected are probably expressed at physiologically significant levels. First, we have shown that the seminested PCR protocol which we used does not detect leaky transcription of AE mRNA in negative control tissues known not to express significant levels of an AE transcript (see ``Materials and Methods''). Second, the transcripts are detected from cDNA derived from very few cells. AE2 message is detected after only 30 cycles of PCR from the equivalent of as few as 2.5 cells (one-cell stage), and AE3 is detected from as few as 5 cells (two-cell stage) using semi-nested PCR. Third, every AE mRNA was not detected at every embryo stage indiscriminately, as would be expected for leaky transcription.

AE2 message must necessarily be produced from both the maternal and embryonic genomes, since it is present before and after the two-cell stage, where the overall switch from maternal to embryonic gene expression occurs in the mouse. AE3 would thus seem to be a product of the embryonic genome only.

It appears that preimplantation stage mouse embryos make mRNA for at least two members of the AE HCO(3)/Cl exchanger family AE2 and AE3. This makes the polypeptides encoded by the AE2 and AE3 genes good candidates for mediating the pH(i) regulatory HCO(3)/Cl exchange activity which we have demonstrated in the preimplantation embryo. It is evident that, of these two anion exchangers, AE2 is the most likely to be responsible for HCO(3)/Cl exchange activity at the one-cell stage: there is robust HCO(3)/Cl exchange activity at the one-cell stage (Fig. 3), but little or no AE3 message detectable at this stage, while in contrast there is a strong AE2 RT-PCR signal. However, it still must be shown directly which AE mRNAs are translated into proteins in the plasma membranes of embryos and that these proteins are responsible for the observed HCO(3)/Cl exchange activity and pH(i) regulation.

Conclusions

We have shown that preimplantation mouse embryos express the message for at least two HCO(3)/Cl exchangers, AE2 and AE3. One or both of these may mediate the HCO(3)/Cl exchange activity previously shown to regulate pH(i) at the two-cell stage and shown here to exist throughout preimplantation development. Exchanger activity is necessary for maintaining embryo pH(i), and in conditions where the external environment is even moderately alkaline, as may exist in the oviduct, embryo development depends on functional HCO(3)/Cl exchange.


FOOTNOTES

*
This work was supported by Medical Research Council of Canada Operating Grant MT12040 (to J. M. B. and National Institutes of Health Grants RO1 HD29533 (to J. M. B.) and RO1 DK43495 (to S. L. A.). A preliminary account of a portion of this work has been published as an abstract(30) . The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. A perliminary account of a portion of this work has been published ad an abstract(30) .

§
These authors contributed equally.

Funded by the Loeb Medical Research Institute.

**
Recipient of a Loeb Medical Research Institute Summer Studentship.

§§
Established Investigator of the American Heart Association.

¶¶
MRC Scholar. To whom correspondence should be addressed: Loeb Medical Research Institute, Ottawa Civic Hospital, 1053 Carling Ave., Ottawa, Ontario K1Y 4E9, Canada. Tel.: 613-798-5555 (ext. 3714); Fax: 613-761-5327; jay{at}civich.ottawa.on.ca.

(^1)
The abbreviations used are: DIDS, 4,4`-diisothiocyanostilbene-2,2`-disulfonic acid; SNARF-1, carboxyseminapthorhodafluor-1; SNARF-1-AM, acetoxymethylester derivative of SNARF-1; PMSG, pregnant mare serum gonadotropin; hCG, human chorionic gonadotropin; ANOVA, analysis of variance; PCR, polymerase chain reaction; RT, reverse transcribed.

(^2)
Y. Zhao and J. M. Baltz, unpublished results.


ACKNOWLEDGEMENTS

We thank Shelley Scott and Jasloveleen Sohi for excellent technical support and John D. Biggers, Timothy Bestor, Jeff Yoder, Johné Liu, Susan Palmieri, and Joel Lawitts for very helpful discussions and suggestions.


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