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A bradykinin-potentiating peptide (BPP-10c) from Bothrops jararaca induces changes in seminiferous tubules

Abstract

Background

The testis-specific isoform of angiotensin-converting enzyme (tACE) is exclusively expressed in germ cells during spermatogenesis. Although the exact role of tACE in male fertility is unknown, it clearly plays a critical function in spermatogenesis. The dipeptidase domain of tACE is identical to the C-terminal catalytic domain of somatic ACE (sACE). Bradykinin potentiating peptides (BPPs) from snake venoms are the first natural sACE inhibitors described and their structure-activity relationship studies were the basis for the development of antihypertensive drugs such as captopril. In recent years, it has been showed that a number of BPPs - including BPP-10c - are able to distinguish between the N- and C-active sites of sACE, what is not applicable to captopril. Considering the similarity between tACE and sACE (and since BPPs are able to distinguish between the two active sites of sACE), the effects of the BPP-10c and captopril on the structure and function of the seminiferous epithelium were characterized in the present study. BPP-10c and captopril were administered in male Swiss mice by intraperitoneal injection (4.7 μmol/kg for 15 days) and histological sections of testes were analyzed. Classification of seminiferous tubules and stage analysis were carried out for quantitative evaluation of germ cells of the seminiferous epithelium. The blood-testis barrier (BTB) permeability and distribution of claudin-1 in the seminiferous epithelium were analyzed by hypertonic fixative method and immunohistochemical analyses of testes, respectively.

Results

The morphology of seminiferous tubules from animals treated with BPP-10c showed an intense disruption of the epithelium, presence of atypical multinucleated cells in the lumen and degenerated germ cells in the adluminal compartment. BPP-10c led to an increase in the number of round spermatids and total support capacity of Sertoli cell in stages I, V, VII/VIII of the seminiferous epithelium cycle, without affecting BTB permeability and the distribution of claudin-1 in the seminiferous epithelium. Interestingly, no morphological or morphometric alterations were observed in animals treated with captopril.

Conclusions

The major finding of the present study was that BPP-10c, and not captopril, modifies spermatogenesis by causing hyperplasia of round spermatids in stages I, V, and VII/VIII of the spermatogenic cycle.

Bradykinin-potentiating peptide; Snake venom; Angiotensin-converting enzyme; Testis; Seminiferous epithelium


Background

Spermatogenesis takes place in the seminiferous epithe­lium of the mammalian testis. The germ cells residing in the basal compartment must traverse the blood-testis barrier (BTB) and enter the adluminal compartment for further development into round, elongated spermatids [ 1. Su W, Mruk DD, Cheng CY: Regulation of actin dynamics and protein trafficking during spermatogenesis-insights into a complex process . Crit Rev Biochem Mol Biol 2013, 48 (2):153-172. ]. The inter-Sertoli tight junctions (TJ) constitute the BTB that protects the seminiferous epithelium from in­vasion by molecules or cells that may disturb the process of spermatogenesis. At the same time, this permeability barrier needs to be temporarily removed at particular stages of spermatogenesis for the movement of germ cells across the seminiferous epithelium [ 2. Cheng CY, Wong EW, Yan HH, Mruk DD: Regulation of spermatogenesis in the microenvironment of the seminiferous epithelium: new insights and advances . Mol Cell Endocrinol 2010, 315(1-2):49-56. ]. TJ is a multimolecular membrane that comprises integral membrane pro­teins, including occludin and claudin family proteins [ 2. Cheng CY, Wong EW, Yan HH, Mruk DD: Regulation of spermatogenesis in the microenvironment of the seminiferous epithelium: new insights and advances . Mol Cell Endocrinol 2010, 315(1-2):49-56. , 3. Morrow CM, Mruk DD, Cheng CY, Hess RA: Claudin and occludin expression and function in the seminiferous epithelium . Philos TRoy Soc B 2010, 365 (1546):1679-1696. ].

Testis-specific isoform of angiotensin-converting enzyme (tACE) is exclusively expressed in maturing germ cells and spermatozoa, but not in Sertoli cells, Leydig cells or any other somatic cell in male adults, suggesting that it is related to the spermiogenesis process [ 4. El-Dorry HA, Bull HG, Iwata K, Thornberry NA, Cordes EH, Soffer RL: Molecular and catalytic properties of rabbit testicular dipeptidyl carboxypeptidase . J Biol Chem 1982, 257 (23):14128-14133.

. Hagaman JR, Moyer JS, Bachman ES, Sibony M, Magyar PL, Welch JE, Smithies O, Krege JH, O'Brien DA: Angiotensin-converting enzyme and male fertility . Proc Natl Acad Sci USA 1998, 95 (5):2552-2557.

. Pauls K, Fink L, Franke FE: Angiotensin-converting enzyme (CD143) in neoplastic germ cells . Lab Invest 1999, 79 (11):1425-1435.
- 7. Pauls K, Metzger R, Steger K, Klonisch T, Danilow S, Franke FE: Isoforms of angiotensin I-converting enzyme in the development and differentiation of human testis and epididymis . Andrologia 2003, 35 (1):32-43. ]. Experimental evidence using tACE knockout models (-/-) indicates that this enzyme is directly associated with male fertility, but its exact role remains unknown [ 5. Hagaman JR, Moyer JS, Bachman ES, Sibony M, Magyar PL, Welch JE, Smithies O, Krege JH, O'Brien DA: Angiotensin-converting enzyme and male fertility . Proc Natl Acad Sci USA 1998, 95 (5):2552-2557. , 8. Esther CR, Marino EM, Howard TE, Machaud A, Corvol P, Capecchi MR, Bernstein KE: The critical role of tissue angiotensin-converting enzyme as revealed by gene targeting in mice . J Clin Invest 1997, 99 (10):2375-2385.

. Krege JH, John SW, Langenbach LL, Hodgin JB, Hagaman JR, Bachman ES, Jennette JC, O'Brien DA, Smithies O: Male-female differences in fertility and blood pressure in ACE-deficient mice . Nature 1995, 375 (6527):146-148.

10 Ramaraj P, Kessler SP, Colmenares C, Sen GC: Selective restoration of male fertility in mice lacking angiotensin-converting enzymes by sperm-specific expression of the testicular isozyme . J Clin Invest 1998, 102 (2):371-378.
- 1111 Kessler SP, Rowe TM, Gomos JB, Lessler PM, Sen GC: Physiological non-equivalence of the two isoforms of angiotensin-converting enzyme . J Biol Chem 2000, 275 (34):26259-26264. ]. It has been reported that tACE is able to release the extracellular portion of glycosylphosphatidylinositol (GPI)-anchored proteins, and it is directly and specifically implicated in egg fertilization by the sperm, independent of its peptidase activity [ 1212 . Deguchi E, Tani T, Watanabe H, Yamada S, Kondoh G: Dipeptidase-inactivated tACE action in vivo: selective inhibition of sperm-zona pellucida binding in the mouse . Biol Reprod 2007, 77 (5):794-802. , 1313 . Kondoh G, Watanabe H, Tashima Y, Maeda Y, Kinoshita T: Testicular angiotensin-converting enzyme with different glycan modification: characterization on glycosylphosphatidylinositol-anchored protein releasing and dipeptidase activities . J Biochem 2009, 145 (1):115-121. ].

Somatic angiotensin I-converting enzyme (sACE) is a well-characterized zinc dipeptidyl carboxypeptidase that plays a pivotal role in the regulation of blood pressure by converting angiotensin I into angiotensin II and by inactivating bradykinin [ 1414 . Ondetti MA, Cushman DW: Inhibition of the renin-angiotensin system: a new approach to the therapy of hypertension . J Med Chem 1981, 24 (4):355-361. ]. sACE has two highly hom­ologous active sites, one at the C-domain and another at the N-domain, each of which is catalytically active and functionally independent [ 1515 . Wei L, Clauser E, Alhenc-Gelas F, Corvol P: The two homologous domains of human angiotensin I-converting enzyme interact differently with competitive inhibitors . J Biol Chem 1992, 267 (19):13398-13405. ]. tACE is distinguish­able from sACE because it has only the active site of the C-domain, preceded by an additional N-terminal sequence [ 1616 . Ehlers MR, Fox EA, Strydom DJ, Riordan JF: Molecular cloning of human testicular angiotensin-converting enzyme: the testis isozyme is identical to the C-terminal half ofendothelial angiotensin-converting enzyme . Proc Natl Acad Sci USA 1989, 86 (20):7741-7745. ].

Bradykinin potentiating peptides (BPPs) from Bothrops jararaca snakes were the first natural sACE inhibitors described. Studies of their structure-activity relationships were the basis for the development of antihypertensive drugs, such as captopril [ 1717 . Cushman DW, Ondetti MA: Inhibitors of angiotensin-converting enzyme for treatment of hypertension . Biochem Pharmacol 1980, 29 (13):1871 -1877. ]. Typically, BPPs contain 5 to 13 amino acid residues with a pyroglutamyl residue (<E) at the N-terminus and a proline residue at the C-terminus. BPPs longer than seven amino acids share similar features, including a high content of proline residues and the tripeptide sequence Ile-Pro-Pro at the C-terminus [ 1818 . Camargo AC, Ianzer D, Guerreiro JR, Serrano SM: Bradykinin-potentiating peptides: beyond captopril . Toxicon 2012, 59 (4):516-523. ].

We found that BPP-10c (<ENWPHPQIPP) is able to distinguish between the two domains of sACE and displays distinct hypotensive effects on rats [ 1919 . Cotton J, Hayashi MA, Cuniasse P, Vazeux G, Ianzer D, De Camargo AC, Dive V: Selective inhibition of the C-domain of angiotensin I converting enzyme by bradykinin potentiating peptides . Biochemistry 2002, 41 (19):6065-6071. , 2020 . Hayashi MA, Murbach AF, Ianzer D, Portaro FC, Prezoto BC, Fernandes BL, Silveira PF, Silva CA, Pires RS, Britto LR, Dive V, Camargo AC: The C-type natriuretic peptide precursor of snake brain contains highly specific inhibitors ofthe angiotensin-converting enzyme . J Neurochem 2003, 85 (4):969-977. ]. In addition, among other BPPs from snake venom, BPP-10c is the most selective inhibitor for the active site at the C-domain of sACE (Ki(app) =0.5nM)[ 1919 . Cotton J, Hayashi MA, Cuniasse P, Vazeux G, Ianzer D, De Camargo AC, Dive V: Selective inhibition of the C-domain of angiotensin I converting enzyme by bradykinin potentiating peptides . Biochemistry 2002, 41 (19):6065-6071. ].Captopril, for instance, is 2.8-orders of magnitude less effective than BPP-10c as an inhibitor of the C-site of sACE [ 2121 . Michaud A, Williams TA, Chauvet MT, Corvol P: Substrate dependence of angiotensin I-convertinng enzyme inhibition: captopril displays a partial selectivity for inhibition ofN-acetyl-seryl-aspartyl-lysyl-proline hydrolysis compared with that of angiotensin I . Mol Pharmacol 1997, 51 :1070-1076. ]. In recent years, we have supported the hypothesis that diverse biological functions for each BPP could be mediated by different interactions with alternative targets, including that BPP-10c is internalized by HUVEC, HEK293 and C6 cells [ 2222    Silva CA, Ianzer DA, Portaro FC, Konno K, Faria M, Fernandes BL, Camargo AC: Characterization of urinary metabolites from four synthetic bradykinin potentiating peptides (BPPs) in mice . Toxicon 2008, 52 (3):501-507.

23 . Silva CA, Portaro FC, Fernandes BL, Ianzer DA, Guerreiro JR, Gomes CL, Konno K, Serrano SM, Nascimento N, Camargo AC: Tissue distribution in mice of BPP 10c, a potent proline-rich anti-hypertensive peptide of Bothrops jararaca . Toxicon 2008, 51 (4):515-523.

24 . Guerreiro JR, Lameu C, Oliveira EF, Klitzke CF, Melo RL, Linares E, Augusto O, Fox JW, Lebrun I, Serrano SM, Camargo AC: Argininosuccinate synthetase is a functional target for a snake venom anti-hypertensive peptide: role in arginine and nitric oxide production . J Biol Chem 2009, 284 (30):20022-20033.
- 2525 . de Oliveira EF, Guerreiro JR, Silva CA, Benedetti GF, Lebrun I, Ulrich H, Lameu C, Camargo AC: Enhancement of the citrulline-nitric oxide cycle in astroglioma cells by the proline-rich peptide-10c from Bothrops jararaca venom . Brain Res 2010, 1363 :11 -19. ]. These results are not surprising, considering that BPP-10c is a proline-rich peptide, a feature that endows this molecule with the properties of cell-penetrating peptides and resistance to proteolysis.

Considering the structural similarity between the C-domain of sACE and tACE, it was observed that tACE male knockout mice were severely hypofertile, tACE was exclusively expressed in maturing germ cells, BPP-10c had selectivity for the active site at the C-domain of sACE and it could be internalized by different cells, and ACE inhibitors could affect the function of the seminiferous epithelium, particularly spermiogenesis [ 5. Hagaman JR, Moyer JS, Bachman ES, Sibony M, Magyar PL, Welch JE, Smithies O, Krege JH, O'Brien DA: Angiotensin-converting enzyme and male fertility . Proc Natl Acad Sci USA 1998, 95 (5):2552-2557. , 7. Pauls K, Metzger R, Steger K, Klonisch T, Danilow S, Franke FE: Isoforms of angiotensin I-converting enzyme in the development and differentiation of human testis and epididymis . Andrologia 2003, 35 (1):32-43. , 9. Krege JH, John SW, Langenbach LL, Hodgin JB, Hagaman JR, Bachman ES, Jennette JC, O'Brien DA, Smithies O: Male-female differences in fertility and blood pressure in ACE-deficient mice . Nature 1995, 375 (6527):146-148. , 1818 . Camargo AC, Ianzer D, Guerreiro JR, Serrano SM: Bradykinin-potentiating peptides: beyond captopril . Toxicon 2012, 59 (4):516-523. , 2222    Silva CA, Ianzer DA, Portaro FC, Konno K, Faria M, Fernandes BL, Camargo AC: Characterization of urinary metabolites from four synthetic bradykinin potentiating peptides (BPPs) in mice . Toxicon 2008, 52 (3):501-507. , 2424 . Guerreiro JR, Lameu C, Oliveira EF, Klitzke CF, Melo RL, Linares E, Augusto O, Fox JW, Lebrun I, Serrano SM, Camargo AC: Argininosuccinate synthetase is a functional target for a snake venom anti-hypertensive peptide: role in arginine and nitric oxide production . J Biol Chem 2009, 284 (30):20022-20033. , 2525 . de Oliveira EF, Guerreiro JR, Silva CA, Benedetti GF, Lebrun I, Ulrich H, Lameu C, Camargo AC: Enhancement of the citrulline-nitric oxide cycle in astroglioma cells by the proline-rich peptide-10c from Bothrops jararaca venom . Brain Res 2010, 1363 :11 -19. ]. Although the in vitro nanomolar range inhibition of hu­man tACE by BPP-5a (<EKWAP) and BPP-9a (<EWPRP-QIPP) has been reported, there are no reports on the possible effects of BPPs in the structure and function of the seminiferous epithelium [ 2626 . Farias SL, Sabatini RA, Sampaio TC, Hirata IY, Cezari MH, Juliano MA, Sturrock ED, Carmona AK, Juliano L: Angiotensin I-converting enzyme inhibitor peptides derived from the endostatin-containing NC1 fragment of human collagen XVIII . J Biol Chem 2006, 387 (5):611-616. ]. Thus, the aim of the current study was to compare the effect of BPP-10c and captopril on spermatogenesis in male mice in order to evaluate the morphological and morphometric pa­rameters, distribution of claudin-1 and analysis of BTB permeability in the seminiferous epithelium.

Methods

Animals

Male Swiss mice (weighting 30 to 35 g) were bred at the Butantan Institute (São Paulo, Brazil). Animals were housed at a temperature of 22°C, had access to water and food ad libitum, and were subjected to a light-dark cycle (12 hours each). The experimental protocols were performed in accordance with the guidelines of the Butantan Institute for the humane use of laboratory ani­mals and were approved by local authorities (protocol number 369/07).

Reagents

All chemicals were of analytical reagent grade, purchased from Calbiochem-Novabiochem Corp. (USA), Merck (USA) and Sigma-Aldrich Corp. (USA) for peptide syn­thesis; captopril and bradykinin were purchased from Sigma Chemical Co (USA).

Peptide synthesis

BPP-10c (<ENWPHPQIPP) was synthesized using auto­mated solid-phase synthesis via Fmoc (9-fluorenylmethy­loxycarbonyl) strategy [ 2323 . Silva CA, Portaro FC, Fernandes BL, Ianzer DA, Guerreiro JR, Gomes CL, Konno K, Serrano SM, Nascimento N, Camargo AC: Tissue distribution in mice of BPP 10c, a potent proline-rich anti-hypertensive peptide of Bothrops jararaca . Toxicon 2008, 51 (4):515-523. ]. The final deprotected peptide was purified by semi-preparative HPLC using an Econosil C-18 column (10 μm, 22.5 mm x 250 mm) and a two-solvent system: (A) TFA/H2O (1:1000) and (B) TFA/ACN/ H2O (1:900:100). The column was eluted at a flow rate of 5 mL/minute over 20 minutes with a 10 to 50% gra­dient of solvent B, and the effluent was detected with an SPD-10AV Shimadzu UV-vis detector, monitored by absorbance at 220 nm. The molecular weight and purity of synthetic peptide were checked via MALDI-TOF mass spectrometry using an Ettan MALDI-TOF/Pro system (Amersham Biosciences, Sweden) and cinnamic acid as a matrix. The peptide concentration was determined by amino acid analysis after acid hydrolysis in vacuum-sealed tubes at 110°C for 22 hours with HCl 6 N containing 1% phenol. Samples were subjected to amino acid analysis using a pico Tag station.

Treatment of animals with BPP-10c and captopril

Male adult mice (30-35 g) were assigned to groups (five animals per group) and treated for 15 days (once a day) by intraperitoneal injection with 4.7 μmol/kg/day of BPP-10c or captopril, diluted in 100 μL of 0.91% w/v aqueous sodium chloride solution. The control group consisted of treatment with vehicle only. The dose of BPP-10c used in the experiments was in agreement with Silva et al. [ 2323 . Silva CA, Portaro FC, Fernandes BL, Ianzer DA, Guerreiro JR, Gomes CL, Konno K, Serrano SM, Nascimento N, Camargo AC: Tissue distribution in mice of BPP 10c, a potent proline-rich anti-hypertensive peptide of Bothrops jararaca . Toxicon 2008, 51 (4):515-523. ]. Mice were killed by CO2 asphyxiation after treatment and testes were collected for morphological, morphometric and immunohistochemical ana­lyses of seminiferous epithelium. BTB permeability studies were carried out in mice treated with BPP-10c, captopril (the same dose, 4.7 μmol/kg/day), lipopoly-saccharide (LPS, 166 μmol/kg/day - positive control) or vehicle (0.91% w/v aqueous sodium chloride solution -negative control) for 15 days. All treatments and exper­iments were performed in duplicate or triplicate.

Morphological and morphometric analyses

The testes of mice treated with BPP-10c, captopril or vehicle were immediately immersed and fixed in Bouin's solution for 24 hours. The samples were dehydrated in ethanol, and embedded in Paraplast® (Sigma Chemical Co., USA) and sectioned at 4 μm thickness. Histological sections were stained with periodic acid-Schiff's (PAS) with Harris hematoxylin counterstaining (for morphometric analysis), or Mallory's trichrome stain (for morphological analysis). Images were taken using a Pixera camera (Pixera Corporation, USA) mounted on a Zeiss Axioskop 2 photo-microscope and captured with a Intel Pentium® computer using Adobe Photoshop 7.0.1 (Adobe Systems, USA).

The stages of the seminiferous epithelium cycle were characterized based on the development of the acrosomic system and morphology of the developing spermatid nucleus [ 2727 . Russell LD, Sinha-Hikim AP, Ettlin RA, Clegg ED: Evaluation of the testis: histo-logical and histopatholological. 1st edition. Clearwater: Cache River Press; 1990. ]. Four spermatogenic stages (I, V, VII/VIII, and XII), representing beginning, middle and end of sem­iniferous epithelium cycle were chosen for quantitative evaluation [ 2828 . Kaneto M, Kanamori S, Hishikawa A, Kishi K: Epididymal sperm motion as a parameter of male reproductive toxicity: sperm motion, fertility, and histopathology in ethinylestradiol-treated rats . Reprod Toxicol 1999, 13 (4):279-289. ]. Four round or nearly-round seminiferous tubule cross-sections per animal were randomly selected for each spermatogenic stage and the following parameters were measured: epithelium height, tubule diameter and lumen diameter using NIH image software (developed at the U.S. National Institutes of Health and available at http://rsb.info.nih.gov/nih-image). The germ cell nuclei (type A spermatogonia; type B spermatogonia; prelepto-tene spermatocyte; zygotene spermatocyte; meiotic figures; secondary spermatocyte; pachytene spermatocyte; round spermatid) and Sertoli cell nucleoli present at stages I, V, VII/VIII, and XII of the seminiferous epithelium cycle were counted using Adobe Photoshop 7.0.1. Total support capacity of each Sertoli cell was obtained by the ratios of total number of germ cells to total number Sertoli cell nucleoli for each stage.

Distribution of claudin-1 by immunohistochemistry

Testis sections from mice treated with BPP-10c, captopril or vehicle were processed according to the Streptavidin-Biotin-peroxidase Complex (SBC) protocol. After deparaffi­nization and dehydration, the sections were pretreated with 0.03% H2O2 for 30 minutes, at room temperature, to block endogenous peroxidase activity. Samples were then washed in phosphate-buffered saline pH 7.4 (PBS), two times for 5 minutes each, and immersed in a solution containing 5% fat-free dry milk (Molico, Nestlé®)inPBS for 15 minutes to block non-specific binding sites.

Sections were incubated overnight at 4°C with anti-rabbit claudin-1 antiserum (MH25- Zymed/Invitrogen®, lot 50393527, cat. no. 71-7800) diluted (1:250) in 0.05 M Tris-HCl with 1% bovine serum albumin (BSA). They were washed in PBS three times for 5 minutes and incu­bated with the diluted biotinylated anti-rabbit IgG for 30 minutes, then washed in PBS three times for 5 minutes and incubated for 30 minutes with Streptavidin-biotin-peroxidase complex. Immunoreactive sites were revealed using a buffered solution of 3,3'-diaminobenzidine-tet-rahydrochloride (DAB) (Dako cytomation®, USA). The sections were dehydrated, mounted and analyzed in a Zeiss Axioskop 2 photomicroscope and the images were captured by Pixera (Pixera Corporation, USA). As negative control, normal rabbit IgG (Vector Laboratories) was used instead of the first antibody in every experiment. Hema-toxylin was used for counterstaining. We also performed immunoblot analysis of mouse testis lysate to assess the specificity of anti-rabbit claudin-1 antibody.

Analysis of BTB by hypertonic fixative method

Mice treated with BPP-10c, captopril, LPS or vehicle were perfused with a hypertonic fixative of 5% glutaraldehyde, 0.05 M sodium cacodylate, and 10% dextrose [ 2929 . Russell L: Desmosome-like junctions between Sertoli and germ cells in the rat testis . Am J Anat 1977, 148 (3):301 -312. ]. Testes were removed and fixed by immersion in hypertonic fixa­tive for 2 hours at 4°C. The testes were washed in 0.05 M sodium cacodylate buffer for 10 minutes, cut in half trans­versely, post-fixed in 1% osmium tetroxide, and embedded in Paraplast® following standard procedures. Hatf-um-thick sections were stained with hematoxylin and eosin.

Statistical analysis

All statistical evaluations were performed either by one-way analysis of variance (ANOVA) followed by the Bonferroni range test or by Student's t-test (GraphPad Prism 4.0, GraphPad Software, Incorporation). The cri­teria for statistical significance were set at p< 0.05.

Results

Effect of BPP-10c on the seminiferous epithelium in male adult mice

The seminiferous tubules observed in animals treated with vehicle ( Figure 1 - A) and captopril ( Figure 1 - B) displayed normal testicular tissue with typical seminiferous epithelium after 15 days of treatment. In contrast, testes of animals treated with BPP-10c ( Figure 1 - CtoF) presented atypical multinucleated cells in the lumen, degenerated germ cells in the adluminal compartment, disruption of the epithelium, and loss of elongated spermatids in the tubules. No alterations in the number of spermatogonia, preleptotene spermatocytes, zygotene spermatocytes, pachytene spermatocytes, or Sertoli cells were detected after treatment with BPP-10c, captopril or vehicle ( Table 1 ). However, the treatment with BPP-10c led to an increase in the number of round spermatids in stages I, V, VII/VIII ( Table 1 ).

Figure 1
Morphological analysis of the seminiferous epithelium of male adult mice treated with BPP-10c and captopril. Photomicrographs of the seminiferous tubules of male adult mice treated with vehicle (A), captopril (B) and BPP-10c (C, D, E, F) using Mallory’s trichrome stain. The seminiferous tubule morphological data obtained from the animals treated with BPP-10c indicated the presence of atypical cells in the lumen (arrow), disruption of the epithelium (*), and a loss of elongated spermatids (#). No alteration was observed in the seminiferous epithelium from mice treated with captopril or vehicle.

Table 1
Quantitative analysis of germinal cells in male adult mouse seminiferous epithelium treated with vehicle (C), captopril (CAP) or BPP-10c (10c)

Epithelium height increased and lumen diameter decreased in the testes of the animals treated with BPP-10c, but no alteration was detected in the tubule diameter when compared with vehicle ( Figure 2 - A).

Figure 2
Morphometric analysis of the seminiferous epithelium of male adult mice treated with BPP-10c or captopril. (A) Morphometric aspects of the seminiferous tubules of control and treated animals (epithelium height, tubule diameter and lumen diameter). (B) Total support capacity of Sertoli cell increased during stages I, V, VII/VIII and XII of the seminiferous epithelium cycle when animals were treated with BPP-10c. Data are presented as mean ± SEM, and the criteria for statistical significance were set at p < 0.05.

Furthermore, BPP-10c increased the total support capacity of Sertoli cell in stages I, V, VII/VIII of the seminiferous epithelium cycle, but not in stage XII (Figure 2 - B). Interestingly, no significant differences were showed in morphometrical parameters analyzed in the testis of the animals treated with captopril when compared with vehicle or BPP-10c ( Figure 2 -A and B).

Immunohistochemical localization of claudin-1 in the seminiferous epithelium after BPP-10c treatment

Claudin-1 was observed in the mouse testis tissue lysates through immunoblot analysis using anti-claudin-1 anti­body, detected as a single band at approximately 20 kDa ( Figure 3-A ). The localization of immunoreactive claudin-1 in the seminiferous epithelium appeared as reddish-brown precipitate in the basal compartment of normal mouse seminiferous tubules ( Figure 3 - B, C and D). Non-­specific staining was only detected in the seminiferous epithelium of control sections, illustrating that the im­munoreactivity is specific for claudin-1 ( Figure 3 - E). Immunoreactive claudin-1 precipitates formed in the basal and adluminal compartments of each tubule in every stage of the germinal epithelium cycle. Moreover, immunoreactive specificity could be observed in the nucleus of premeiotic germ cells, but not in pachytene spermatocytes, secondary spermatocytes, or round sper-matids. Likewise, the distribution of claudin-1 following captopril (Figure 3 - F and G) and BPP-10c (Figure 3 - H and I) treatments was the same as that of seminiferous epithelium in untreated mice.

Figure 3
Effects of BPP-10c and captopril on the distribution of claudin-1 in the seminiferous epithelium of adult mouse testis. (A) Immunoblot analysis of mouse testis lysate using an antibody to claudin-1. (B, C, D) Immunohistochemical staining of mouse testis transverse cross-sections treated with vehicle. (E) Non-specific staining was detected only in the basal and adluminal compartments of seminiferous epithelium of control sections – negative control. (F and G) Immunostaining of claudin-1 following treatment with captopril or (H and I) BPP-10c demonstrated no difference in the distribution of claudin-1 when compared with control. Hematoxylin was used for counterstaining. Scale bar: 50 μm.

Analysis of BTB permeability

The barrier can be visualized in testes fixed with a dextrose-containing hypertonic fixative. The permeability of BTB was examined in testicular sections of mice treated with vehicle, captopril, BPP-10c or LPS. Cells directly ex­posed to the fixative, such as those on the basal side of the barrier, suffer the osmotic effects of the dextrose and shrink, leaving large intercellular gaps. Because dextrose cannot transverse the BTB, cells on the luminal side are protected from the hypertonicity of the fixative and maintain close apposition with one another. The BTB was maintained in testes of mice treated with vehicle, captopril and BPP-10c ( Figure 4 - A, B and C, respectively, see arrows). However, the barrier was not intact following LPS treatment and cells throughout the cross-section of the tubule shrank away from each other ( Figure 4 - D, see arrow). LPS is known to com­promise testicular function [ 3030 . O'Bryan MK, Schlatt S, Phillips DJ, de Kretser DM, Hedger MP: Bacterial lipopolysaccharide-induced inflammation compromises testicular function at multiple levels in vivo . Endocrinology 2000, 141 (1):238-246. ].

Figure 4
Maintenance of the blood-testis barrier (BTB) in male adult mice treated with vehicle, captopril or BPP-10c. Photomicrographs of 0.5-μm thick – plastic-embedded transverse sections of (A) vehicle, (B) captopril, (C) BPP-10c and (D) LPS – of seminiferous tubules following fixation with hyperosmotic fixative and staining with hematoxylin and eosin. The adluminal meiotic cells are protected from fixative-induced condensation, maintaining normal morphology and cellular contacts in A, B and C (arrow). The BTB is not maintained in the seminiferous tubules of mice treated with LPS (D, see arrow).

Discussion

The major finding of the present study was that BPP-10c, the most potent and selective sACE C-domain inhibitor, modified spermatogenesis in mice without affecting BTB permeability or the distribution of claudin-1, a protein found at the site of the BTB [ 1919 . Cotton J, Hayashi MA, Cuniasse P, Vazeux G, Ianzer D, De Camargo AC, Dive V: Selective inhibition of the C-domain of angiotensin I converting enzyme by bradykinin potentiating peptides . Biochemistry 2002, 41 (19):6065-6071. ]. Interestingly, captopril, which is also an inhibitor of sACE, did not show any effect on spermatogenesis probably due to the inability of this ACE active-site directed inhibitor to cross the BTB. In fact, it has been described that sACE inhibitors (captopril and derivates) did not affect tACE activity in vivo, suggesting that these drugs are limited in testicular penetration by the BTB [ 3030 . O'Bryan MK, Schlatt S, Phillips DJ, de Kretser DM, Hedger MP: Bacterial lipopolysaccharide-induced inflammation compromises testicular function at multiple levels in vivo . Endocrinology 2000, 141 (1):238-246. , 3131 . Sakaguchi K, Chai SY, Jackson B, Johnston CI, Mendelsohn FA: Inhibition of tissue angiotensin converting enzyme: quantitation by autoradiography . Hypertension 1988, 11 (3):230-238. ].

Morphologic investigation of testes in adult mice indi­cated a clear alteration in the seminiferous epithelium following BPP-10c treatment. Alterations were observed in stages I, V, VII/VIII in round spermatids, while no such alterations were observed following captopril treatment.

The effects of BPP-10c treatment also included an in­crease in the height of the epithelium and a decrease in the diameter of the tubule lumen, as well as an increase in the total support capacity of Sertoli cells, indicating that BPP-10c inhibited spermiogenesis. In fact, tACE is only found in round spermatids in the seminiferous tubules, with levels increasing markedly during further differentiation [ 7. Pauls K, Metzger R, Steger K, Klonisch T, Danilow S, Franke FE: Isoforms of angiotensin I-converting enzyme in the development and differentiation of human testis and epididymis . Andrologia 2003, 35 (1):32-43. ]. The observed effects of BPP-10c could be explained by the interaction with tACE, which causes alterations in its dipeptidase and/or GPI-anchored protein-releasing activities, leading to an inhibition of maturation with an increase in the number of round spermatids.

Claudin-1 expression has been demonstrated in the testis and culture of mouse Sertoli cells, but we have shown in the current study for the first time its distribu­tion in mouse seminiferous epithelium [ 3232 . Jackson B, Cubela RB, Johnston CI: Effects of perindopril on angiotensin converting enzyme in tissues of the rat. J Hypertens Suppl 1988, 6(3):S51 -S54. ]. Other studies have indicated that claudin-1 expression in the epididy-mis is not exclusively limited to TJ, but appears along the entire interface of adjacent epithelial cells, as well as along the basal plasma membrane [ 3333    Gye MC: Expression of claudin-1 in mouse testis . Arch Androl 2003, 49 (4):271 -279. ]. We demon­strated that claudin-1 is found in the basal and adlum-inal compartments in the seminiferous epithelium of normal mice, suggesting that claudin-1 may have func­tions other than those involving TJ in the testis and epididymis. Moreover, Gregory et al. [ 3434 .  Gregory M, Dufresne J, Hermo L, Cyr D: Claudin-1 is not restricted to tight junctions in the rat epididymis . Endocrinology 2001, 142 (2):854-863. ] identified claudin-1 in the nucleus as an intracellular signaling molecule that either diffuses or is actively transported to the nucleus from the site of cell-cell adhesion by mitogen-activated protein kinase kinase 2 (MEK2) in pancreatic cells. MEK2, an isoform of mitogen-activated protein kinases (MAPKs), is found in all premeiotic germ cells and spermatocytes, and is implicated in chromatin condensation during the division of male germ cells [ 3535    Tan X, Egami H, Ishikawa S, Kurizaki T, Nakagawa M, Hirota M, Ogawa M: Arrangement of expression and distribution of tight junction protein claudin-1 in cell dissociation of pancreatic cancer cells . Int J Oncol 2004, 25 (6):1567-1574.

36 . Inselman A Handel MA: Mitogen-activated protein kinase dynamics during the meiotic G2/MI transition of mouse spermatocytes . Biol Reprod 2004, 71 (2):570-578.
- 3737 . Sette C, Barchi M, Bianchini A, Conti M, Rossi P, Geremia R: Activation of the mitogen-activated protein kinase ERK1 during meiotic progression of mouse pachytene spermatocytes . J Biol Chem 1999, 274 (47):33571 -33579. ]. In fact, our immunohistochemical studies showed that claudin-1 is expressed in premeiotic germ cells, with a pattern similar to that of MEK2 expression. These results suggest that claudin-1 participates in chromatin condensa­tion of germ cells by signaling through MEK2.

The localization of claudin-1 in the seminiferous epi­thelium was examined to assess its possible changes in the BTB during the BPP-10c-induced spermatogenesis damage. No alterations were shown in the distribution of claudin-1 in animals treated with BPP-10c, captopril, or vehicle, suggesting that the peptide did not alter BTB integrity. Some chemicals disrupt this barrier and increase its permeability, but we have shown that treatment with BPP-10c did not alter BTB permeability, suggesting that the peptide could cross the BTB and interact with tACE or others targets [ 3030 . O'Bryan MK, Schlatt S, Phillips DJ, de Kretser DM, Hedger MP: Bacterial lipopolysaccharide-induced inflammation compromises testicular function at multiple levels in vivo . Endocrinology 2000, 141 (1):238-246. , 3838    Di Agostino S, Rossi P, Geremia R, Sette C: The MAPK pathway triggers activation of Nek2 during chromosome condensation in mouse spermatocytes . Development 2002, 129 (7):1715-1727. , 3939 . Su L, Cheng CY, Mruk DD: Adjudin-mediated Sertoli-germ cell junction disassembly affects Sertoli cell barrier function in vitro and in vivo . In J Biochem Cell B 2010, 42 (11):1864-1875. ].This hypothesis seems to represent a real possibility, since a growing number of peptides, including toxins, have been shown to penetrate cells [ 2525 . de Oliveira EF, Guerreiro JR, Silva CA, Benedetti GF, Lebrun I, Ulrich H, Lameu C, Camargo AC: Enhancement of the citrulline-nitric oxide cycle in astroglioma cells by the proline-rich peptide-10c from Bothrops jararaca venom . Brain Res 2010, 1363 :11 -19. , 4040 . Su L, Mruk DD, Lie PP, Silvestrini B, Cheng CY: A peptide derived from laminin-y3 reversibly impairs spermatogenesis in rats . Nat Commun 2012, 3 :1185. , 4141 . Joliot A, Prochiantz A: Transduction peptides: from technology to physiology . Nat Cell Biol 2004, 6 :189-196. ]. Besides, we demonstrated that BPP-10c was internalized by HEK-293 T and HUVEC cells, but the mechanism is yet unknown and it opens new perspectives to study their internalization by Sertoli cell culture [ 2323 . Silva CA, Portaro FC, Fernandes BL, Ianzer DA, Guerreiro JR, Gomes CL, Konno K, Serrano SM, Nascimento N, Camargo AC: Tissue distribution in mice of BPP 10c, a potent proline-rich anti-hypertensive peptide of Bothrops jararaca . Toxicon 2008, 51 (4):515-523. , 2424 . Guerreiro JR, Lameu C, Oliveira EF, Klitzke CF, Melo RL, Linares E, Augusto O, Fox JW, Lebrun I, Serrano SM, Camargo AC: Argininosuccinate synthetase is a functional target for a snake venom anti-hypertensive peptide: role in arginine and nitric oxide production . J Biol Chem 2009, 284 (30):20022-20033. ].

Conclusion

In summary, this study demonstrated that BPP-10c, a po­tent selective C-domain inhibitor of ACE from B. jararaca venom, inhibits spermiogenesis in mice without affecting the distribution of claudin-1 or the permeability of BTB. Further analyses will contribute to a better understanding of the molecular mechanism underlying the effects of BPPs from snake venom in the testicular physiology, adding new biological features to the whole venom.

Ethics committee approval

All experimental protocols described in the present study were performed in accordance with the guidelines for use of laboratory animals of Butantan Institute and approved by local authorities (protocol number 369/07).

Acknowledgments

This work was supported by the State of São Paulo Research Foundation (FAPESP) through the Center for Applied Toxinology (CAT-CEPID). The authors are grateful to Cruz A. M. Rigonati (Institute of Biomedical Sciences, University of São Paulo) for histological support and wish to thank Dr Sofia Ribeiro for the fruitful discussions. Thanks are also due to Dr. Robson L. Melo and Clécio F. Klitzke for technical assistance in synthesis and MALDI-TOF mass spectrometry analysis of the peptide, and Neusa Lima and Maria José da Silva for secretarial assistance.

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Publication Dates

  • Publication in this collection
    2013

History

  • Received
    4 May 2013
  • Accepted
    25 Oct 2013
Centro de Estudos de Venenos e Animais Peçonhentos (CEVAP/UNESP) Av. Universitária, 3780, Fazenda Lageado, Botucatu, SP, CEP 18610-034, Brasil, Tel.: +55 14 3880-7693 - Botucatu - SP - Brazil
E-mail: editorial.jvatitd@unesp.br