Journal of Histochemistry and Cytochemistry, Vol. 46, 855-862, July 1998, Copyright © 1998, The Histochemical Society, Inc.


ARTICLE

Localization of Carbonic Anhydrase IV in Rat and Human Heart Muscle

Susanne Sendera, Brigitte Deckerb, Christiane D. Fenskec, William S. Slyd, Nicholas D. Carterc, and Gerolf Grosa
a Vegetative Physiologie, Zentrum Physiologie, Medizinische Hochschule Hannover, Hannover, Germany
b Zellbiologie und Elektronenmikroskopie, Zentrum Anatomie, Medizinische Hochschule Hannover, Hannover, Germany
c Medical Genetics Unit, St George's Hospital Medical School, London, United Kingdom
d Edward A. Doisy Department of Biochemistry and Molecular Biology, St Louis University School of Medicine, St Louis, Missouri

Correspondence to: Susanne Sender, Vegetative Physiologie, 4220, Medizinische Hochschule Hannover, 30623 Hannover, Germany.


  Summary
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Summary
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Materials and Methods
Results
Discussion
Literature Cited

We investigated carbonic anhydrase IV (CA IV) in rat and human heart with immunohistochemical methods by both light and electron microscopy. In cryosections that were incubated with anti-CA IV/FITC, the capillaries showed a strong reaction for CA IV. In paraffin and semithin sections treated with anti-CA IV/ABC (avidin–biotin–peroxidase complex) blood vessels, capillaries, and sarcolemma (SL) were positively stained. By staining ultrathin sections with anti-CA IV/immunogold, CA IV could also be demonstrated at the latter two locations, including the specialized sarcolemmal structures intercalated discs, and T-tubules. In addition, by this method CA IV was seen to be associated with the sarcoplasmic reticulum (SR). The absence of immunostaining in SR and/or SL with some techniques probably indicates a problem of accessibility of the antigenic sites. In line with the immunohistochemical results, CA IV mRNA expression was visualized in both endothelial and muscle cells by in situ hybridization histochemistry. (J Histochem Cytochem 46:855–861, 1998)

Key Words: carbonic anhydrase IV, capillaries, sarcolemma, sarcoplasmic reticulum, heart, skeletal muscle, immunohistochemistry, in situ hybridization


  Introduction
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

SEVERAL STUDIES have provided evidence for the existence of carbonic anhydrase (CA) in mammalian heart muscle. De Hemptinne et al. 1987 obtained indirect evidence for the presence of an extracellular sarcolemmal CA from surface pH measurements in cardiac muscle preparations. Lagadic-Gossmann et al. 1992 concluded from pHi measurements in isolated guinea pig ventricular myocytes that the efficiency of acid extrusion by an Na+/HCO3- symport is dependent on CA activity. Romanowski et al. 1992 demonstrated facilitated CO2 diffusion in cardiac muscle, a process for which intracellular CA activity is essential. In contrast to mammalian skeletal muscle, no cytosolic form of CA was detectable in cardiac muscle, but high CA activity was found in the membrane fraction of heart muscle homogenates (Geers et al. 1992 ). Bruns and Gros 1992 described CA activity in sarcolemmal and sarcoplasmic reticulum vesicles from bovine hearts and, in addition, presented histochemical evidence for an intracellular membrane-bound CA.

A membrane-bound CA, CA IV, has been shown by immunohistochemistry to be present in capillary endothelium of rat and human skeletal muscles (Sender et al. 1994 ) and in sarcolemma (SL) and sarcoplasmic reticulum (SR) of rat muscle (Decker et al. 1996 ). CA IV was also detected by immunoblotting in rat skeletal and heart muscle (Waheed et al. 1992 ). With a modified Hansson technique, Vandenberg et al. 1996 showed CA to be present in capillary endothelium and SL of ferret heart and, from perfusion experiments, inferred a significant role for CA in cardiac pH regulation.

The purpose of this study was to investigate in heart muscle the localization of membrane-bound CA IV to different cells and subcellular structures. Antisera against CA IV were used in various techniques to immunostain sections of rat and human heart for visualization of CA IV at light microscopic and electron microscopic levels. Furthermore, in situ hybridization (ISH) histochemistry was applied to determine the presence of CA IV mRNA. This technique was carried out on human heart muscle sections and, in view of the immunohistochemical results for CA IV in skeletal muscle mentioned above, also on human skeletal muscle sections.


  Materials and Methods
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Materials and Methods
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Tissue Preparation
Pieces of rat and human heart muscle were dissected and frozen in liquid nitrogen. Human heart muscle samples were obtained from explanted hearts of patients undergoing transplantation. The samples were taken from unaffected tissue portions immediately after explantation. Cryosections were screened to exclude tissue specimens with visible degradation. Other sections 5–7 µm thick intended for further processing were fixed and stored as decribed by Sender et al. 1994 .

In addition, pieces of heart muscle were fixed for 4–6 hr in one of the following fixatives: (a) 2.5% glutaraldehyde/2% paraformaldehyde in 0.1 M sodium cacodylate-HCl buffer, pH 7.3; (b) 0.1% glutaraldehyde/4% paraformaldehyde in the same buffer; (c) 3% glutaraldehyde in the same buffer; or (d) paraformaldehyde/lysine/periodate (PLP) in 0.1 M phosphate buffer as described by Yu 1993 . For semithin and ultrathin sections, the tissue specimens were postfixed for 1 hr with 1% OsO4 and 1.5% K4[Fe(CN)6] dissolved in 0.1 M sodium cacodylate-HCl buffer, pH 7.3 (Karnovsky 1971 ). After dehydration the samples were embedded in Epon 812 (Serva; Heidelberg, Germany) or in LR White resin (LRW), medium grade (Plano; Marburg, Germany). Some of the heart muscle specimens that were fixed as described in d were embedded in paraffin.

Immunohistochemistry
Preparation and specificity of the applied antisera, anti-rat lung CA IV and anti-human lung CA IV, were previously described (Brown et al. 1990 ; Zhu and Sly 1990 ).

Light Microscopy
The cryosections were stained by immunofluorescence according to Sender et al. 1994 . Paraffin sections 2–3 µm thick were mounted on poly-L-lysine-coated slides (Sigma; Deisenhofen, Germany), deparaffinized, and rehydrated through xylene and graded ethanol. They were then treated with 0.25% trypsin (Seromed; Berlin, Germany) in PBS at 37C for 20 min. Endogenous peroxidase was blocked by incubation in 1% H2O2 in methanol for 10 min. The sections were rinsed in 5% normal swine serum diluted in 0.05 M Tris-HCl buffer (pH 7.6) and then immunostained by the avidin–biotin–peroxidase complex (ABC) technique, following the protocol described by Decker et al. 1996 . Semithin sections of epoxy resin–embedded tissue were cut at 1 µm with an LKB 4800-III ultratome and mounted on poly-L-lysine-coated slides. After removal of the epoxy resin by sodium methoxide (Mayor et al. 1961 ), the sections were immunostained by the ABC technique as mentioned above.

Electron Microscopy
Ultrathin sections about 80 nm thick were etched with a saturated solution of sodium metaperiodate for 30 min. They were incubated overnight at 4C with a solution of 0.1% BSA/5% goat nonimmune serum/0.05 M Tris-HCl, pH 7.6, and anti-CA IV (diluted 1:200–1:500). Sections were further treated according to the protocol given by Decker et al. 1996 . The size of the immunogold particles was 10–15 nm. Control sections were incubated either with rabbit nonimmune serum (Sigma), with the same dilutions as for the antisera, or with antigen-blocked antisera according to Sender et al. 1994 .

Generation of Single-stranded Riboprobes
Full-length single-stranded riboprobes (sense and anti-sense) were synthesized from full-length 1105-base pair (BP) CA IV cDNA (Okuyama et al. 1992 ), using an SP6/T7 transcription kit (Boehringer; Mannheim, Germany), and labeled with [35S]-UTP according to the manufacturer's protocol.

In Situ Hybridization
Human skeletal muscle samples were frozen in liquid nitrogen. Cryosections 10 µm thick were mounted on TESPA-coated slides (Sigma). The sections were fixed in 4% paraformaldehyde in PBS for 20 min. They were then incubated with 25 µg/ml pronase E (Sigma) in 50 mM Tris/5 mM EDTA, pH 7.4, for 10 min at 37C. The sections were refixed in 4% paraformaldehyde in PBS for 10 min at room temperature, washed in PBS, and dehydrated in 70% ethanol. After prehybridization at 37C for 2 hr, the sections were hybridized overnight at 37C with the [35S]-UTP-labeled human CA IV riboprobes. Experimental tissue sections were incubated with the anti-sense CA IV riboprobe and control sections with the sense riboprobe. After stringent washing (Kelly et al. 1991 ), the sections were dehydrated, air-dried, and coated with Ilford K5 photographic emulsion for autoradiography. After exposure for 18 hr the slides were developed and fixed. Counterstaining was performed with hematoxylin/eosin.


  Results
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Materials and Methods
Results
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Light Microscopy
Immunofluorescence Method: CA IV in Capillary Endothelium. Incubation of heart muscle cryosections with anti-CA IV/FITC resulted in positive staining of the capillary endothelium in rat (Figure 1A) and human heart (Figure 1B). The muscle cells showed no apparent staining. Control sections incubated with nonimmune serum/FITC showed only background fluorescence (Figure 1C). Therefore, the immunostaining indicates the association of CA IV with heart capillaries.



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Figure 1. Cryosections from rat heart (A) and human heart (B) incubated with anti-CA IV/FITC, showing bright fluorescence of capillaries. (C) Control section to (B), incubated with rabbit nonimmune serum/FITC. Capillaries show no staining. Bars = 30 µm.

Figure 2. (A) Paraffin section of PLP-fixed rat heart, immunostained with anti-CA IV/avidin–biotin–peroxidase complex. Capillaries (arrowheads), SL (arrows), and the endothelium of blood vessels (BV) are positively stained. (B) Semithin section of PLP-fixed, Epon-embedded rat heart incubated with anti-CA IV/ABC. Immunostaining is seen in capillary walls (arrowheads) and SL (arrows). (C) Control section to B, showing only weak unspecific staining after incubation with rabbit nonimmune serum/ABC. Bars = 20 µm.

Figure 3. In situ hybridization for CA IV mRNA in cryosections from human heart (A) and human skeletal muscle (C). Blue staining of the nuclei and reddish color of the cytoplasm are seen after counterstaining with hematoxylin/eosin. Silver grains indicate the reaction of [35S]-UTP-labeled anti-sense RNA probe with CA IV-specific mRNA. Blood vessels (BV) and several nuclei (N) show a strong signal. A weaker positive signal is exhibited by the cytoplasm. (B) Control section to A, using [35S]-UTP-labeled sense RNA probe. Few silver grains indicate unspecific background labeling. Bars = 40 µm.

Avidin–Biotin–Peroxidase Complex Method: CA IV in Vascular Endothelium and Sarcolemma. After incubation with anti-CA IV/ABC, paraffin sections of rat heart showed intense brown staining in the capillary endothelium and the endothelium of blood vessels (Figure 2A). A positive reaction was also seen at the SL, which exhibited a brown color of variable intensity. The cytoplasm in only some of the cardiac muscle cells showed yellowish staining, which was also seen in control sections (not shown). We conclude, therefore, that CA IV is present in the vascular endothelium and in the SL. This result is confirmed by semithin sections of rat cardiac muscle incubated with anti-CA IV/ABC or nonimmune serum/ABC, respectively. There was strong SL and capillary staining in parts of the antiserum-treated sections (Figure 2B). With this technique, the capillary staining appeared not only on the luminal but also on the external surface of the capillary wall. As in the cryosections (Figure 1A and Figure 1B) and in the ABC-treated paraffin sections (Figure 2A), the cytoplasm showed no specific staining. In the control sections, almost no immunoreactivity was visible throughout the sections (Figure 2C).

In Situ Hybridization to CA IV-specific mRNA. The hybridization of isotope-labeled riboprobe with tissue intrinsic CA IV mRNA transcripts was shown in heart (Figure 3A) and skeletal muscle (Figure 3C). In cardiac muscle sections, an intense hybridization signal was seen in many nuclei and, to a lesser extent in the cytoplasm. In control sections (Figure 3B) in which a sense RNA probe was used, the amount of silver grains was significantly reduced. On the basis of the number and distribution of the positive nuclei, one can conclude that both cardiomyocytes and capillary endothelial cells express CA IV. In addition, in both heart and skeletal muscle sections there was a prominent signal in larger blood vessels. This is shown in Figure 3C for skeletal muscle, together with a high signal intensity over nuclei and a lower signal intensity in the cytoplasm. Because the nuclei of skeletal muscle cells are often close to capillaries, it is sometimes difficult to unequivocally attribute the signal to one of these cell types. However, some capillaries showing accumulation of siver grains can definitely be identified. Therefore, we conclude that there may be an identical pattern of CA IV mRNA expression in heart and skeletal muscle.

Electron Microscopy
The applied fixatives and embedding media gave similar results regarding intensity and localization of the CA IV immunoreaction. Figure 4F shows a section from human heart; the other sections were taken from rat cardiac muscle.



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Figure 4. Ultrathin sections of heart tissue fixed with 2.5% glutaraldehyde/2% paraformaldehyde and embedded in Epon (A,C,D,F–I) or fixed with PLP and embedded in LRW (B,E). (F) A section from human heart; all other sections are from rat heart. Sections shown in A–H were incubated with anti-CA IV/immunogold; a control section (I) was incubated with antigen-blocked CA IV antiserum/immunogold. (A,B) Gold particles are accumulated in endothelial cells (arrowheads), mostly at the luminal membrane. (C) Clusters of gold particles are present over the SL (arrowheads). (D) A positive reaction is seen at the intercalated discs ID (arrowheads). (E) Patches of gold particles at the level of a Z disc (Z) indicate staining of T-tubules and/or SR. (F) Immunostaining is observed close to the intercalated discs (ID) (arrowheads). (G) Terminal cisternae (TC) and T-tubule (T) exhibit postitive staining. Z, Z disc. (H) SR membranes show accumulation of gold particles. (I) Control section showing almost no unspecific staining. To quantitatively substantiate the difference between antiserum-treated and control sections, we evaluated the particle density over a total area of 1.5 µm2 of capillary endothelium. A total of 46 immunogold particles was obtained after incubation with anti-CA IV, whereas an identical area in control sections showed only two particles. Bars = 0.2 µm.

CA IV in Capillary Endothelium. After incubation with anti-CA IV/immunogold, capillary endothelial cells showed an accumulation of gold particles, predominantly in the proximity of the luminal membrane (Figure 4A and Figure 4B).

CA IV in the Sarcolemma. The SL, too, exhibited strong immunoreaction for CA IV (Figure 4C). Furthermore, CA IV appeared to be associated with specialized sarcolemmal structures, intercalated discs and T-tubules. As shown in Figure 4D and Figure 4F, patches of gold particles were found next to the intercalated discs. Very few particles were observed within the cells. An accumulation of gold particles could also be seen associated with membranous structures close to the Z discs (Figure 4E). We interpret this staining pattern as a positive reaction of T-tubules, which extend inward from the cell surface at this site, and/or as staining of junctional SR.

CA IV in Sarcoplasmic Reticulum. CA IV inside the muscle cells themselves is shown in Figure 4G and Figure 4H. Clusters of gold particles were associated with junctional complexes between sarcolemma and SR membrane, situated at the level of Z discs. In Figure 4G, both junctional SR and T-tubules are positively stained, whereas mitochondria remain unstained. Figure 4G shows an example of a triadic junctional complex, although the majority of junctional complexes in heart are diadic. What are called "terminal cisternae" in Figure 4G are much smaller in heart than in skeletal muscle and may not be wider than the L-system in general. In the longitudinal system, seen to be located between the myofibrils, we also found CA IV (Figure 4H). Control sections incubated with antigen-blocked antiserum/immunogold showed almost no background staining throughout the whole section (Figure 4I).

The ultrathin sections therefore support and extend the light microscopic results mentioned above. CA IV is located on the luminal membrane of capillary endothelial cells and is associated with SL and SR of cardiac muscle cells.


  Discussion
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

CA IV in Capillary Endothelium
The localization of CA IV in capillary endothelium of heart muscle is consistent with our earlier demonstration of CA IV in skeletal muscle capillaries (Sender et al. 1994 ; Decker et al. 1996 ). As in skeletal muscle, electron microscopy shows CA IV to be associated with the endothelial luminal membrane both in human and rat heart. Using the modified Hansson technique, Vandenberg et al. 1996 have shown CA to be located in capillary endothelium of ferret heart. In their sections, as in our semithin sections (Figure 2B), staining for CA activity was apparent both at the luminal and the external capillary surface. The modified Hansson technique does not allow the identification of the specific CA isozyme involved. From Western blots, showing a reaction of crude ferret heart homogenates with anti-bovine CA IV, the authors concluded that the CA, stained by the Hansson technique, is likely to be CA IV.

Concerning the physiological role of this CA, Forster and Crandall 1975 have shown that a capillary CA can accelerate CO2 uptake by the blood during capillary transit. The significance of endothelial CA IV in larger blood vessels remains to be ascertained.

CA IV in the Sarcolemma
As in skeletal muscle (Sender et al. 1994 ; Decker et al. 1996 ), CA IV could be detected in heart muscle SL in semithin and ultrathin sections but not in cryosections. On the one hand, the higher sensitivity of the ABC technique compared with the immunofluorescence method may contribute to this finding. On the other hand, as discussed for skeletal muscle sections, this probably also indicates a problem of accessibil-ity (Decker et al. 1996 ). As can be seen in Figure 2A and Figure 2B, SL staining becomes apparent in locations at which the antibodies have easiest access to the outer surface of the SL. This access may be facilitated by the ABC technique, which uses fixation media that lead to considerable cell shrinkage and hence to a widening of the intercellular spaces. The present immunohistochemical results showing CA IV associated with the SL and with specific sarcolemmal structures, the intercalated discs and the T-tubules, agree with the histochemical localization of CA as described by Vandenberg et al. 1996 . With the Hansson technique, staining for CA in addition to capillaries was apparent at the SL in longitudinal sections and was most prominent in the region of the intercalated discs. As the authors pointed out, it would require electron microscopy to unequivocally demonstrate that this CA is indeed associated with endothelial as well as sarcolemmal membranes. In the present study we confirm at the electron microscopic level that CA IV is associated with the capillary luminal membrane and with the SL. CA at the latter location may have a function in pH regulation (De Hemptinne et al. 1987 ; Lagadic-Gossmann et al. 1992 ; Vandenberg et al. 1996 ).

CA IV in the Sarcoplasmic Reticulum
In heart muscle, SR CA IV could be demonstrated at the electron microscopic but not at the light microscopic level, a phenomenon that has also been observed in skeletal muscle sections (Sender et al. 1994 ; Decker et al. 1996 ). However, in cryosections of rabbit heart, Bruns and Gros 1992 did report an intracellular staining for CA with dansylsulfonamide (DNSA), a fluorescent CA inhibitor. The staining appeared to be associated with intracellular structures and was interpreted as a positive reaction of SR and T-tubules. On the other hand, Vandenberg et al. 1996 found no intracellular staining for CA activity with the modified Hansson method, consistent with our present light microscopic results. As has been discussed with regard to skeletal muscle (Decker et al. 1996 ), a problem of accessibility of CA IV to the histochemical reagent appears to exist. Supposing that CA is mainly oriented towards the SR interior, as was shown for skeletal muscle (Geers et al. 1991 ; Gros et al. 1993 ), only lipophilic substances such as DNSA, but not macromolecules, such as antibodies, may be able to penetrate the SR membranes and react with an intra-SR enzyme epitope. Only in ultrathin sections of 80 nm is the section thickness less than the thickness of longitudinal tubules, so that free access of antibodies to the intra-SR CA is expected. In all thicker sections, a major part of the SR may be present as an intact, closed membranous network into which antibodies cannot enter. The same problem may exist for the reagents used in the Hansson technique, which may not gain access to the active center of the enzyme inside the SR.

It has been postulated that CA in skeletal muscle SR is necessary to rapidly produce and buffer H+ that move across the SR membrane in exchange for Ca++ (Wetzel et al. 1990 ). CA IV in heart muscle SR may play an anologous role, as has been indicated by results of Geers and Gros 1995 .

CA IV mRNA Expression in Endothelium and Muscle Cells
The ISH histochemistry clearly shows that CA IV mRNA is present in heart muscle and skeletal muscle cells as well as in capillaries and other vessels. This is in accordance with the immunohistochemical results presented above, indicating the synthesis of CA IV in the same cell types that exhibit CA IV immunoreactivity.

The percentage similarities between human CA IV and other human CAs present in skeletal muscle cells and/or erythrocytes are 31% for CA I, 36% for CA II, and 30% for CA III at the amino acid level (Okuyama et al. 1992 ). Considering that the percentage homology at the nucleotide level will be even lower, we believe that nonspecific hybridization of the riboprobe to mRNAs of other CA isozymes is eliminated by the use of stringent washing procedures.


  Acknowledgments

Supported by the Deutsche Forschungsgemeinschaft, grant Gr 489/10.

The excellent technical assistance of Iris Albers and Elke Mallon and the expert photographic assistance of Angelika Hundt, are gratefully acknowledged.

Received for publication September 17, 1997; accepted March 11, 1998.


  Literature Cited
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Summary
Introduction
Materials and Methods
Results
Discussion
Literature Cited

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