Hostname: page-component-cd9895bd7-q99xh Total loading time: 0 Render date: 2024-12-26T18:34:15.726Z Has data issue: false hasContentIssue false

Morphological evaluation of adult domestic cat testicular biopsy after vitrification

Published online by Cambridge University Press:  13 May 2024

Julyne Vivian Guimarães de Carvalho
Affiliation:
Laboratory of Wild Animal Biotechnology and Medicine, Faculty of Veterinary Medicine, Federal University of Pará, Castanhal, Pará, Brazil Postgraduate Programme in Animal Health and Production in the Amazon, Federal Rural University of Amazonia, Belém, Pará, Brazil
Airton Renan Bastos Soares
Affiliation:
Laboratory of Wild Animal Biotechnology and Medicine, Faculty of Veterinary Medicine, Federal University of Pará, Castanhal, Pará, Brazil
Inara Tayná Alves Evangelista
Affiliation:
Laboratory of Wild Animal Biotechnology and Medicine, Faculty of Veterinary Medicine, Federal University of Pará, Castanhal, Pará, Brazil
Danuza Leite Leão
Affiliation:
Laboratory of Wild Animal Biotechnology and Medicine, Faculty of Veterinary Medicine, Federal University of Pará, Castanhal, Pará, Brazil
Regiane Rodrigues dos Santos
Affiliation:
Laboratory of Wild Animal Biotechnology and Medicine, Faculty of Veterinary Medicine, Federal University of Pará, Castanhal, Pará, Brazil
Sheyla Farhayldes Souza Domingues*
Affiliation:
Laboratory of Wild Animal Biotechnology and Medicine, Faculty of Veterinary Medicine, Federal University of Pará, Castanhal, Pará, Brazil Postgraduate Programme in Animal Health and Production in the Amazon, Federal Rural University of Amazonia, Belém, Pará, Brazil
*
Corresponding author: Sheyla Farhayldes Souza Domingues; Email: shfarha@ufpa.br
Rights & Permissions [Opens in a new window]

Summary

Testicular biopsies (9 mm3) from domestic cats (n = 10) submitted to orchiectomy were submitted to equilibrium vitrification in the presence of ethylene glycol (EG) alone or combined with dimethylsulfoxide (DMSO) as intracellular cryoprotectants, and sucrose or trehalose as extracellular cryoprotectants. The samples were vitrified with 40% EG or 20% EG + 20% DMSO, plus 0.1 M or 0.5 M of sucrose or trehalose. The study was divided into Step 1 and Step 2. In Step 1, intratubular cells (spermatogonia, spermatids, spermatocytes, and Sertoli cells) were quantified and classified as intact or degenerated (pyknotic and/or vacuolated cells). Cryodamage of seminiferous cords was determined by spermatogonia and Sertoli cell scoring of nuclei alterations, tubular basement membrane detachment, epithelium shrinkage, and tubular measures (total area, epithelium area, larger and smaller diameter, and height of the epithelium). In Step 2, Hoechst 33342 stain and propidium iodide (PI) fluorescent stain were used to assess the cell viability of the four best experimental groups in Step 1. The effect of treatments on all analyses was accessed using analysis of variance (ANOVA), and Fisher’s post hoc test at P < 0.05 significance was considered. In Step 1, the mean percentage of spermatogonia and Sertoli cells morphological integrity did not show a difference when using both sugars at different concentrations, but their morphology was more affected when DMSO was used. EG use associated with 0.1 M of sucrose or trehalose positively affected spermatocyte and spermatid morphology, respectively. The larger diameter and epithelium height of seminiferous tubules were increased using DMSO plus 0.5 M sucrose and DMSO plus 0.1 M trehalose. The changes in spermatogonial/Sertoli nucleoli visualization were best scored in the EG groups, while the nuclei condensation was lower with sucrose. The basement membrane was satisfactorily preserved with 0.1 M sucrose. In Step 2, the percentage of cell viability was higher when EG plus 0.1 M sucrose was used. Therefore, DMSO’s negative effect on the vitrification of testicular biopsies of adult domestic cats was evident. The EG plus 0.1 M of sucrose or trehalose associations are the most suitable CPAs to preserve the testicular histology structure of adult domestic cats in vitrification.

Type
Research Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

Improving reproductive techniques to preserve genetic material from endangered wild cats is needed due to the number of feline species on the International Union for Conservation of Nature and Natural Resources (IUCN) Red List of Endangered Species. Worldwide, there are 38 endangered feline species, and only seven species are not in danger of extinction (International Union for Conservation of Nature and Natural Resources, 2020). The most obvious example is the domestic cat (Felis catus). The phylogenetic proximity between domestic and wild felids, allows their use as an experimental model for the development of procedures to preserve reproductive cells (Sowińska, Reference Sowińska2021). In reproductively ageing males, cryopreservation of testis biopsies appears to be the only alternative to preserve the genetic potential of animals that unexpectedly die (Comizzoli and Wildt, Reference Comizzoli and Wildt2013). The mature testicular tissue allows access to all stages of the sperm cycle, which would be in vitro cultured or grafted by xenotransplant to produce viable cells for assisted reproduction in the future (Abrishami et al., Reference Abrishami, Anzar, Yang and Honaramooz2010; Comizzoli, Reference Comizzoli2015).

Testicular biopsy equilibrium vitrification is a potential technique for cryopreservation due to its low cost and easy operability (Amorim et al., Reference Amorim, Curaba, Van Langendonckt, Dolmans and Donnez2011). This technique has already been described in humans (Dumont et al., Reference Dumont, Oblette, Rondanino, Jumeau, Bironneau, Liot, Duchesne, Wils and Rives2016), rats (Radaelli et al., Reference Radaelli, Almodin, Minguetti-Câmara, Cerialli, Nassif and Gonçalves2017), fish (Higaki et al., Reference Higaki, Kuwata, Tanaka, Tooyama, Fujioka, Sakai and Takada2017), pigs (Abrishami et al., Reference Abrishami, Anzar, Yang and Honaramooz2010), collared peccary (da Silva et al., Reference da Silva, Bezerra, Praxedes, Moreira, de Souza, de Oliveira, Pereira, Comizzoli and Silva2019) and in prepubertal cats, solid-surface vitrification with 20% dimethylsulfoxide (DMSO), 20% glycerol (GLY) and 24% ethylene glycol (EG) was evaluated (Lima et al., Reference Lima, Jung, Rusch, Usmani, Lopes and Conrad2017a; Lima et al., Reference Lima, Silva, Aquino-Cortez, Leiva-Revilla and Silva2018). However, the method needs to be optimized for mature cats.

EG and DMSO are the most commonly used intracellular cryoprotectants in equilibrium vitrification. They are small molecules that enter the cell and bind with water molecules, limiting the amount of intracellular and extracellular water, which protects intracellular organelles (Prentice and Anzar, Reference Prentice and Anzar2010). DMSO, as the only permeable cryoprotectant, can be toxic at high concentrations (Gurtovenko and Anwar, Reference Gurtovenko and Anwar2007). Conversely, EG reduces the time of the tissue permeabilization process and is a good alternative for the vitrification of human adult testicular biopsy (Unni et al., Reference Unni, Kasiviswanathan, D’Souza, Khavale, Mukherjee, Patwardhan and Bhartiya2012) and epididymal sperm of adult domestic cats (Lima et al., Reference Lima, Soares, Stalker, Santos and Domingues2021). Therefore, the association of both CPAs can be an alternative to increase total penetration and reduce the harmful effects of vitrification (Baert et al., Reference Baert, Goossens, van Saen, Ning and Tournaye2012; Poels et al., Reference Poels, Van Langendonckt, Dehoux, Donnez and Wyns2012).

As extracellular cryoprotectants, sucrose and trehalose are two isomers of a non-reducing disaccharide that can balance the extracellular and intracellular osmotic pressure during vitrification and devitrification, playing a role in cell membrane stabilization (Pan et al., Reference Pan, Yu, Zhang, Wang, Zhu, Liu and Zeng2017). Studies indicate they can interact directly with membrane lipids and proteins, changing their phase transition behaviour and hydration status (Crowe et al., Reference Crowe, Crowe, Carpenter, Rudolph, Wistrom, Spargo and Anchordoguy1988). Therefore, sugars optimize the vitreous transition and increase cell viability (Tian et al., Reference Tian, Zhao, Han, Zhu, Chen, Zhang, Wei, Cao and Zhou2015). Trehalose preserves cell viability and reduces oxidative stress by vitrification in bovine calf testicular tissue (Zhang et al., Reference Zhang, Wang, Han, Hu, Wang and Hu2015), and sucrose was successfully used in the vitrification of testicular tissue in prepubertal cats, maintaining the proliferative potential of cells (Lima et al., Reference Lima, Silva, Morais, Aquino-Cortez, Evangelista, Xavier Júnior, Viana and Silva2017b).

In the present study, we evaluated the effect of EG (40%) alone, associated with DMSO (20% EG + 20% DMSO), combined or not with sucrose (0.1 M or 0.5 M) or trehalose (0.1 M or 0.5 M) on the vitrification of parenchymal testicular tissue in adult domestic cats.

Materials and methods

Chemicals

Unless stated otherwise, all chemicals and media used in this study were purchased from Sigma Chemical Company 43 (St. Louis, MO, USA).

Tissue collection

Ten mixed-breed adult cats (n = 10), aged 1–5 years and weighing 2.5–4 kg, were sterilized by elective orchiectomy in the Veterinary Hospital School, as requested and authorized by their owners. Before the surgical procedure, a clinical examination was performed to detect the animal’s health status, confirmed by a complete blood count and biochemical profile, and the physical examination of the reproductive tract. The evaluation of each male considered testicle consistency, shape, mobility, symmetry, and biometrics (height, length, width, and volume). The cats were submitted to an open bilateral orchiectomy, after which the tests were transported to the laboratory within 30 min in saline solution (0.9% NaCl) at 20°C.

Experimental design

The testicles of five males were divided longitudinally into 18 fragments of 9 mm³. The testicular pieces were allocated to the control or vitrified groups in duplicate. As a control, two samples of each animal were immediately fixed in Davidson fixative for 24 h for histological analysis. The remaining fragments were exposed for 3 min at 20°C to the different equilibrium solutions prepared in phenol red-free RPMI-1640 as the base medium (Brito et al., Reference Brito, Domingues, Silva, Wu, Santos and Pieczarka2016), as follows: 20% EG or 10% EG + 10% DMSO, either combined with sucrose (0.1 or 0.5 M) or trehalose (0.1 or 0.5 M); two fragments per treatment. Subsequently, the tissues were exposed for 2 min at 20°C to the different vitrification solutions, as follows: 40% EG or 20% EG + 20% DMSO, either combined with sucrose (0.1 or 0.5 M) or trehalose (0.1 or 0.5 M); two fragments per treatment. Vitrification was performed using the solid-surface method, as previously described (Santos et al., Reference Santos, Tharasanit, Van Haeften, Figueiredo, Silva and Van den Hurk2007), and tissues were stored in liquid nitrogen (−196°C). After 1 week of storage, the fragments were exposed to room temperature (∼25°C) for 30 s, followed by 1 min in the water bath (37°C) and three subsequent washing steps of 3, 5, and 7 min in RPMI-1640 medium added with decreasing concentrations of sucrose or trehalose, according to the vitrification solution, i.e. 0.05, 0.025, and 0 M for groups vitrified with 0.1 M, and 0.25, 0.125, and 0 for groups vitrified with 0.5 M (Figure 1). After warming, all the fragments were immediately fixed in Davidson fixative and processed for routine histological analysis. The morphological analysis included germ and Sertoli cells integrity, spermatogonia/Sertoli cells nuclei, tubular epithelium score scale, and tubular component morphometry (Figure 2). For this, images were captured with a digital camera (DS-Ri2, Nikon Corporation, Tokyo, Japan) coupled to a light microscope (Eclipse Ni-U, Nikon Corporation, Tokyo, Japan), and measurements were performed with the aid of Nis Elements AR software (4.50.00 64 bit, version 1991–2015, Nikon Corporation, Tokyo, Japan). In total, 30 tubules were evaluated per experimental group.

Figure 1. Experimental design. Performance of testis fragment recovery tests for Steps 1 and 2 (1). Separation of experimental groups and control (2). Exposure of equilibrium solution (ES) and vitrification solution (VS), vitrification process and exposure to warming bath with warming solutions (3). Testis fragments after warming processing and analysis (4).

Figure 2. Germ and Sertoli cells are classified as intact, pyknotic or vacuolization (A). The blue line is the measure of total area, red line is the lumen area, larger and smaller diameters are represented for the yellow and orange lines, respectively (B). Scale bar represents 50 μm.

In experiment 2, the testes of five males were divided longitudinally into 10 fragments of 9 mm³, which were randomly divided in Duplo into control or vitrified groups. Two samples from each animal were submitted to mechanical dissociation of testicular cells as a control. In brief, the two fragments were presented to successive cuts into a Petri dish and recovered by suspension in 1 ml of RPMI medium. The solution was transferred to a Falcon tube, and 20 aliquots were pipetted. After that, a cell strainer (40 μm) was used to recover the isolated cells. The samples were centrifuged at 1000 rpm for 5 min, and 150 μl of the cell suspension was incubated with 2.5 μl of Hoechst-33342 stain (0.5 μg/ml) and 1 μl propidium iodide (PI) (2 μg/ml) for 30 min in a dark room (Lima et al., Reference Lima, Silva, Morais, Aquino-Cortez, Evangelista, Xavier Júnior, Viana and Silva2017b). After incubation, 10 μl of each sample was evaluated, and 200 cells were counted using an epifluorescence microscope (Eclipse Ni-U, Nikon Corporation, Tokyo, Japan) at ×400 magnification. The emitted fluorescence signals of Hoechst stain and PI were collected at 380/535 and 555/645 nm, respectively. Cells were classified as non-viable if stained positively with PI. The remaining fragments were exposed for 3 min at 20°C to the different equilibrium solutions prepared in phenol red-free RPMI 1640 as the base medium (Brito et al., Reference Brito, Domingues, Silva, Wu, Santos and Pieczarka2016), as follows: 20% EG either combined with sucrose (0.1 or 0.5 M) or trehalose (0.1 or 0.5 M); two fragments per treatment. Subsequently, the tissues were exposed for 2 min at 20°C to the different vitrification solutions: 40% EG combined with sucrose (0.1 or 0.5 M) or trehalose (0.1 or 0.5 M); two fragments per treatment. Vitrification and thawing were performed as described in experiment 1. After warming, all the fragments were immediately submitted to the same procedure as the control fragments, and cell viability was assessed.

Statistical analysis

The data are expressed as mean ± standard deviation (SD) and analyzed by the Statview 5.0 program (SAS Institute Inc., Cary, NC, USA). All data were submitted to the Kolmogorov–Smirnov test and underwent a logarithmic transformation. The effect of vitrification on the tubular component measures, percentage of typical germ and Sertoli cells, score scale, and cell viability was assessed by analysis of variance (ANOVA), and differences were located with Fisher’s protected least significant difference (PLSD) post hoc test. A P-value < 0.05 was considered statistically significant.

Results

All males showed testicles with regular consistency, a round shape, free mobility in the scrotum, and normal symmetry.

After vitrification, the percentage of all intact morphological germ and Sertoli cells was statistically different from the control group (Table 1). In the sequence, spermatogonial cells were best preserved in the EG groups when compared with the treatments with DMSO, independent of disaccharides and their concentrations tested (P < 0.0001; Table 1). In the second cell type analyzed, spermatocytes were more preserved morphologically in vitrification, with EG associated with smaller sucrose (P = 0.0075) and trehalose (P = 0.0092) concentrations (Figure 3). In contrast, the highest sucrose concentration plus EG (P = 0.0092). Its small concentration plus DMSO (P = 0.0305) showed the most deleterious effect (Table 1).

Table 1. Percentage of intact germ and Sertoli cells before and after cat testicular parenchyma vitrification

a–dDifferent superscripts indicate significant differences within the same row (P < 0.05).

C: Control; DMSO: dimethylsulfoxide; EG: ethylene glycol; S: sucrose; T: trehalose.

Figure 3. Histological sections of seminiferous tubules of domestic cat stained with haematoxylin and eosin (H&E). All analyses were made at ×400 magnification. Ethylene glycol (EG); dimethylsulfoxide (DMSO); sucrose (S), trehalose (T). Control group (C); EF + 0.1 M S (T1); EF + 0.5 M S (T2); EF + 0.1 M T (T3); EF + 0.5 M T (T4); EF + DMSO+0.1 M S (T5); EF + DMSO + 0.5 M S (T6); EF + DMSO + 0.1 M T (T7); EF + DMSO + 0.5 M T (T8). For Figure T1, the arrow shows normal spermatogonia after vitrification. For Figure T3, the arrow shows normal spermatocytes, and the arrowhead shows a normal Sertoli cell. For Figure T5, the arrow shows tubular basement membrane detachment. For Figure T7, the arrow shows normal spermatids. Scale bars represent 50 μm.

In its turn, spermatid integrity had better results, associating 0.1 M of trehalose with EG (P = 0.0087) or EG + DMSO (P = 0.0031). In addition, the higher concentration of sucrose plus EG showed a harmful effect on them (P = 0.0414; Figure 3). At last, Sertoli cells were susceptible to the DMSO vitrification solutions. In addition, EF + trehalose (0.1 and 0.5 M) solutions resulted in better preservation (Table 3).

Table 2. Tubular measurements and epithelium height before and after testicular tissue vitrification of adult tomcats

a,bDifferent superscripts indicate significant differences within the same column (P < 0.05).

C: Control group; DMSO: Dimethylsulfoxide; EG: Ethylene glycol; S: Sucrose; T: Trehalose.

Table 3. Score scale of cat testicular seminiferous tubules

a–cDifferent superscripts indicate significant differences within the same row (P < 0.05).

DMSO: dimethylsulfoxide; EG: ethylene glycol; S: sucrose; T: trehalose.

The means of total tubule area and area of   seminiferous epithelium did not differ from the control group. Nevertheless, the highest concentration of sucrose in the DMSO-associated groups has a discrete influence in increasing these measures (Table 2). For the larger diameter of the seminiferous tubules, using EF + DMSO with 0.5 M sucrose showed a high increase in this measure (P = 0.0112; Table 2). Smaller diameters have no statistical difference among the groups (Table 2). To seminiferous epithelium height, the DMSO associated with 0.1 M trehalose increases this measurement (P = 0.0405; Table 2).

The control group differed statistically from all experimental groups at scale score parameters (P = 0.0001) (Table 3). There was no difference between the treatments at the spermatogonia and Sertoli cell nuclei distinction score. For nucleoli visualization, both EG groups with 0.1 M or 0.5 M sucrose and 0.1 M trehalose were best scored when compared with others (P = 0.0009). These groups still performed at the nuclei condensation score (P = 0.0073) (Table 3). At basement membrane detachment and epithelium shrinkage, the EG plus 0.1 M group was best rated (P = 0.046; P = 0.0006).

The four EG experimental groups were submitted to Step 2. The control group differed from all treatments except for the EG plus 0.1 M sucrose group (P = 0.225). In addition, the percentage of viable cells (Hoechst +) in this group was increased when compared with the other groups (P = 0.005; Figure 4).

Figure 4. Cell viability accessed by Hoechst-33342 stain and propidium iodide (PI) fluorescence dyes for EG groups at Step 2. (A) Tubular isolated cell emitting fluorescence by Hoechst-33342 stain. (B) Cat testicular cell emitting propidium iodide (PI) stain. (C) Graphic representation of isolated cell viability percentage before and after vitrification process. The columns show the mean and standard deviation of the mean of each experimental group. Sucrose (S); Trehalose (T). Scale bars represents = 50 μm. a–cDifferences indicate significant differences among treatments (P < 0.05).

Discussion

All the associations of intracellular and extracellular cryoprotectants were able to somewhat preserve the morphological integrity of seminiferous tubules. Nevertheless, generally, the groups with DMSO were inferior in preserving germinative cell morphologies. In the groups with EG, the recovery of spermatogonia with viable morphology was higher than in the associated groups, in agreement with previously described results that 40% EG was the best result for immature mouse spermatogonial viability (Gouk et al., Reference Gouk, Loh, Kumar, Watson and Kuleshova2011). These results could be due to EG’s high penetrability and perfusion, which minimize the deleterious effects on testicular cells (Unni et al., Reference Unni, Kasiviswanathan, D’Souza, Khavale, Mukherjee, Patwardhan and Bhartiya2012).

The EF + DMSO association revealed that DMSO is deleterious to cells when used in high concentrations on adult cat testicular biopsies. Nevertheless, DMSO is an effective cryoprotectant associated with glycerol for immature cat testicular tissue when analyzed by similar spermatogonia/Sertoli cells and basement membrane scores (Lima et al., Reference Lima, Jung, Rusch, Usmani, Lopes and Conrad2017a). Therefore, EG showed better results for adult mouse testicular tissue (Unni et al., Reference Unni, Kasiviswanathan, D’Souza, Khavale, Mukherjee, Patwardhan and Bhartiya2012), which justified the most outstanding results of this study. The same protective effect of EG is observed on Sertoli cells, which represents an important tool to support spermatogonia development (Ning et al., Reference Ning, Goossens, Geens, Van Saen and Tournaye2012).

Therefore, it was evident that high concentrations of DMSO induced pore formation in the phospholipid membrane (Gurtovenko and Anwar, Reference Gurtovenko and Anwar2007) and affected the epigenetic regulatory system by altering the methylation profile of DNA (Iwatani et al., Reference Iwatani, Ikegami, Kremenska, Hattori, Tanaka, Yagi and Shiota2006). However, at low concentrations, DMSO induces membrane thinning and increases the fluidity of the membrane’s hydrophobic core (Gurtovenko and Anwar, Reference Gurtovenko and Anwar2007). This mechanism justifies the positive results of slow freezing (Curaba et al., Reference Curaba, Verleysen, Amorim, Dolmans, Van Langendonckt, Hovatta, Wyns and Donnez2011; Pukazhenthi et al., Reference Pukazhenthi, Nagashima, Travis, Costa, Escobar, França and Wildt2015), but the deleterious effect of using DMSO on the vitrification of mature testicular tissue (Hajiaghalou et al., Reference Hajiaghalou, Ebrahimi, Shahverdi, Sharbatoghli and Beigi Boroujeni2016; da Silva et al., Reference da Silva, Bezerra, Praxedes, Moreira, de Souza, de Oliveira, Pereira, Comizzoli and Silva2019) and sperm cells (Xu et al., Reference Xu, Tan, Zhu, Ye, Wang, Zhu, Dahms, Jin and Yang2014). Probably, the concentration of 20% of DMSO in the vitrification solution was enough to induce membrane pores formation and increase the occurrence of membrane rupture, as evidenced by the epithelium score analyses of this study. Based on that, the absence of experimental groups containing only DMSO is explained by the substantial toxicity caused when used at high concentrations.

The percentage of morphologically viable spermatocytes in domestic cats was better in the EG group associated with 0.1 M sucrose or trehalose. However, when associated with 0.5 M sucrose, the effect was deleterious, which could show that the protective effect of sucrose as a nonpermeable CPA was not cumulative, and perhaps in higher concentrations led to unequal dehydration of the cells (Sum et al., Reference Sum, Faller and de Pablo2003). Therefore, the present results were confirmed when the percentage of cell viability was higher at 0.1 M sucrose when compared with other concentrations of sugars, closer to some results that show that sucrose at 210 mmol is more efficient when compared with other smaller and higher concentrations in the vitrification of spermatogonia stem cells in pigs (Pan et al., Reference Pan, Yu, Zhang, Wang, Zhu, Liu and Zeng2017). In addition, the vitrification of the cat epididymal tail shows great preservation of sperm integrity with EG and 0.1 M sucrose vitrification (Lima et al., Reference Lima, Soares, Stalker, Santos and Domingues2021). Unfortunately, the studies on concentrations of sugars in cat testicular biopsies for vitrification are limited, which shows the importance of this research.

Concerning spermatids, the indifference between the use of EG or EG + DMSO with trehalose maybe because this disaccharide has the flexibility to expand and contract its glucose rings and adjust to the proper dimensions between the lipid headgroups, minimizing the effects of the intracellular cryoprotectant (Sum et al., Reference Sum, Faller and de Pablo2003). The sucrose density is highest in the middle of the aqueous region of the membrane. In contrast, trehalose exhibits a uniform distribution throughout the aqueous region (Sum et al., Reference Sum, Faller and de Pablo2003).

The height of the germinal epithelium of adult domestic cats in reproductive age can vary from approximately 55 µm (Hoshino et al., Reference Hoshino, Nakaghi, Pacheco, Lui and Malheiros2002) 67–78 µm (Diagone et al., Reference Diagone, Feliciano, Pacheco and Vicente2012), reaching up to 81 µm (França and Godinho, Reference França and Godinho2003). The association of DMSO with 0.1 M trehalose increases the testicular epithelial height after vitrification, which may be related to the alteration in cell-to-cell junctions and swelling caused by DMSO on testicular tissue (da Silva et al., Reference da Silva, Bezerra, Praxedes, Moreira, de Souza, de Oliveira, Pereira, Comizzoli and Silva2019).

For the larger tubular diameter, although the group with EG + DMSO and trehalose at 0.5 M has shown higher values, these are within the usual range for domestic cat tubular measurements (Hoshino et al., Reference Hoshino, Nakaghi, Pacheco, Lui and Malheiros2002; França and Godinho, Reference França and Godinho2003). The tubular area, epithelium area, and smaller diameter also agree with normospermic domestic cats (Neubauer et al., Reference Neubauer, Jewgenow, Blottner, Wildt and Pukazhenthi2004). Therefore, vitrification does not significantly influence the occurrence of tubular retraction due to cold.

In conclusion, Although all cryoprotectant associations were effective to some degree in preserving the morphological parameters of domestic cat testicular tissue and germ and Sertoli cell integrity. The DMSO-associated groups showed more damage when compared with the EG-associated groups. In addition, the 0.1 M concentration of sucrose was more efficient at recovering the most significant percentage of viable cells after vitrification.

Financial support

The authors thank ‘Coordenação de Aperfeiçoamento de Pessoal de Nível Superior—Brasil (CAPES)—Finance Code 001’ for financial support.

Competing interests

All the authors have no conflict of interest.

Ethical approval

The Research Ethics Committee of the Federal University of Pará approved the study (protocol number: 2890040516).

References

Abrishami, M., Anzar, M., Yang, Y. and Honaramooz, A. (2010). Cryopreservation of immature porcine testis tissue to maintain its developmental potential after xenografting into recipient mice. Theriogenology, 73(1), 8696. doi: 10.1016/j.theriogenology.2009.08.004 CrossRefGoogle ScholarPubMed
Amorim, C. A., Curaba, M., Van Langendonckt, A., Dolmans, M.-M. and Donnez, J. (2011). Vitrification as an alternative means of cryopreserving ovarian tissue. Reproductive Biomedicine Online, 23(2), 160186. doi: 10.1016/j.rbmo.2011.04.005 CrossRefGoogle Scholar
Baert, Y., Goossens, E., van Saen, D., Ning, L., in’t Veld, P. and Tournaye, H. (2012). Orthotopic grafting of cryopreserved prepubertal testicular tissue: In search of a simple yet effective cryopreservation protocol. Fertility and Sterility, 97(5), 1152–7.e1. doi: 10.1016/j.fertnstert.2012.02.010 CrossRefGoogle ScholarPubMed
Brito, D. C., Domingues, S. F. S., Silva, J. K., Wu, X., Santos, R. R. and Pieczarka, J. C. (2016). Detrimental effect of phenol red on the vitrification of cat (Felis catus) ovarian tissue. Biopreservation and Biobanking, 14(1), 1722. doi: 10.1089/bio.2015.0025 CrossRefGoogle ScholarPubMed
Comizzoli, P. (2015). Biobanking efforts and new advances in male fertility preservation for rare and endangered species. Asian Journal of Andrology, 17(4), 640645. doi: 10.4103/1008-682X.153849 CrossRefGoogle ScholarPubMed
Comizzoli, P. and Wildt, D. E. (2013). Mammalian fertility preservation through cryobiology: Value of classical comparative studies and the need for new preservation options. Reproduction, Fertility, and Development, 26(1), 9198. doi: 10.1071/RD13259 CrossRefGoogle Scholar
Crowe, J. H., Crowe, L. M., Carpenter, J. F., Rudolph, A. S., Wistrom, C. A., Spargo, B. J. and Anchordoguy, T. J. (1988). Interactions of sugars with membranes. Biochimica et Biophysica Acta, 947(2), 367384. doi: 10.1016/0304-4157(88)90015-9 CrossRefGoogle Scholar
Curaba, M., Verleysen, M., Amorim, C. A., Dolmans, M.-M., Van Langendonckt, A., Hovatta, O., Wyns, C. and Donnez, J. (2011). Cryopreservation of prepubertal mouse testicular tissue by vitrification. Fertility and Sterility, 95(4), 1229–34.e1. doi: 10.1016/j.fertnstert.2010.04.062 CrossRefGoogle ScholarPubMed
da Silva, A. M., Bezerra, L. G. P., Praxedes, E. C. G., Moreira, S. S. J., de Souza, C. M. P., de Oliveira, M. F., Pereira, A. F., Comizzoli, P. and Silva, A. R. (2019). Combination of intracellular cryoprotectants preserves the structure and the cells proliferative capacity potential of adult collared peccary testicular tissue subjected to solid surface vitrification. Cryobiology, 91, 5360. doi: 10.1016/j.cryobiol.2019.10.199 CrossRefGoogle ScholarPubMed
Diagone, K. V., Feliciano, M. A. R., Pacheco, M. R. and Vicente, W. R. R. (2012). Histology and morphometry of the testes of adult domestic cats (Felis catus). Journal of Feline Medicine and Surgery, 14(2), 124130. doi: 10.1177/1098612X11431531 CrossRefGoogle Scholar
Dumont, L., Oblette, A., Rondanino, C., Jumeau, F., Bironneau, A., Liot, D., Duchesne, V., Wils, J. and Rives, N. (2016). Vitamin A prevents round spermatid nuclear damage and promotes the production of motile sperm during in vitro maturation of vitrified pre-pubertal mouse testicular tissue. Molecular Human Reproduction, 22(12), 819832. doi: 10.1093/molehr/gaw063 Google Scholar
França, L. R. and Godinho, C. L. (2003). Testis morphometry, seminiferous epithelium cycle length, and daily sperm production in domestic cats (Felis catus). Biology of Reproduction, 68(5), 15541561. doi: 10.1095/biolreprod.102.010652 CrossRefGoogle Scholar
Gouk, S. S., Loh, Y. F. J., Kumar, S. D., Watson, P. F. and Kuleshova, L. L. (2011). Cryopreservation of mouse testicular tissue: Prospect for harvesting spermatogonial stem cells for fertility preservation. Fertility and Sterility, 95(7), 23992403. doi: 10.1016/j.fertnstert.2011.03.035 CrossRefGoogle Scholar
Gurtovenko, A. A. and Anwar, J. (2007). Modulating the structure and properties of cell membranes: The molecular mechanism of action of dimethyl sulfoxide. The Journal of Physical Chemistry. B, 111(35), 1045310460. doi: 10.1021/jp073113e CrossRefGoogle Scholar
Hajiaghalou, S., Ebrahimi, B., Shahverdi, A., Sharbatoghli, M. and Beigi Boroujeni, N. (2016). Comparison of apoptosis pathway following the use of two protocols for vitrification of immature mouse testicular tissue. Theriogenology, 86(8), 20732082. doi: 10.1016/j.theriogenology.2016.06.027 CrossRefGoogle Scholar
Higaki, S., Kuwata, N., Tanaka, K., Tooyama, I., Fujioka, Y., Sakai, N. and Takada, T. (2017). Successful vitrification of whole juvenile testis in the critically endangered cyprinid honmoroko (Gnathopogon caerulescens). Zygote, 25(5), 652661. doi: 10.1017/S0967199417000430 CrossRefGoogle Scholar
Hoshino, P., Nakaghi, L. S. O., Pacheco, M. R., Lui, J. F. and Malheiros, E. B. (2002). Morfometria dos túbulos seminíferos e ductos epididimários de cães e gatos provenientes de cirurgia de castração. Biotemas, 15(1), 97110. https://periodicos.ufsc.br/index.php/biotemas/article/view/21647/19640 Google Scholar
International Union for Conservation of Nature and Natural Resources. (2020). The IUCN Red List of Threatened Species. Version 2020–2. https://www.iucnredlist.org. Retrieved July 09, 2023Google Scholar
Iwatani, M., Ikegami, K., Kremenska, Y., Hattori, N., Tanaka, S., Yagi, S. and Shiota, K. (2006). Dimethyl sulfoxide has an impact on epigenetic profile in mouse embryoid body. Stem Cells, 24(11), 25492556. doi: 10.1634/stemcells.2005-0427 CrossRefGoogle Scholar
Lima, A. C., Jung, M., Rusch, J., Usmani, A., Lopes, A. M. and Conrad, D. F. (2017a). A Standardized approach for multispecies purification of mammalian male germ cells by mechanical tissue dissociation and flow cytometry. Journal of Visualized Experiments: JoVE, (125), 111. doi: 10.3791/55913 Google ScholarPubMed
Lima, D., Silva, T., Morais, G. B., Aquino-Cortez, A., Evangelista, J., Xavier Júnior, F., Viana, D. A. and Silva, L. (2017b). Different associations of cryoprotectants for testicular tissue of prepubertal cats submitted to vitrification. Reproduction in Domestic Animals, 52(2) Suppl. 2, 235241. doi: 10.1111/rda.12833 CrossRefGoogle Scholar
Lima, D. B. C., Silva, T. F. P. D., Aquino-Cortez, A., Leiva-Revilla, J. and Silva, L. D. M. D. (2018). Vitrification of testicular tissue from prepubertal cats in cryotubes using different cryoprotectant associations. Theriogenology, 110, 110115. doi: 10.1016/j.theriogenology.2017.12.037 CrossRefGoogle Scholar
Lima, S. L. G., Soares, A. R. B., Stalker, L., Santos, R. R. and Domingues, S. F. S. (2021). Epididymal tail solid-surface vitrification as an effective method for domestic cat sperm cryobanking. Zygote, 29(6), 452458. doi: 10.1017/S096719942100006X CrossRefGoogle ScholarPubMed
Sowińska, N. (2021). The domestic cat as a research model in the assisted reproduction procedures of wild felids. Postepy Biochemii, 67(4), 362369. doi: 10.18388/pb.2021_416 Google Scholar
Neubauer, K., Jewgenow, K., Blottner, S., Wildt, D. E. and Pukazhenthi, B. S. (2004). Quantity rather than quality in teratospermic males: A histomorphometric and flow cytometric evaluation of spermatogenesis in the domestic cat (Felis catus). Biology of Reproduction, 71(5), 15171524. doi: 10.1095/biolreprod.104.031062 CrossRefGoogle Scholar
Ning, L., Goossens, E., Geens, M., Van Saen, D. V. and Tournaye, H. (2012). Spermatogonial stem cells as a source for regenerative medicine. Middle East Fertility Society Journal, 17(1), 17. doi: 10.1016/J.MEFS.2011.06.002 CrossRefGoogle Scholar
Pan, C. Y., Yu, S., Zhang, P. F., Wang, B., Zhu, Z. D., Liu, Y. Y. and Zeng, W. X. (2017). Effect of sucrose on cryopreservation of pig spermatogonial stem cells. Journal of Integrative Agriculture, 16(5), 11201129. doi: 10.1016/S2095-3119(16)61489-2 CrossRefGoogle Scholar
Poels, J., Van Langendonckt, A., Dehoux, J. P., Donnez, J. and Wyns, C. (2012). Vitrification of non-human primate immature testicular tissue allows maintenance of proliferating spermatogonial cells after xenografting to recipient mice. Theriogenology, 77(5), 10081013. doi: 10.1016/j.theriogenology.2011.10.015 CrossRefGoogle Scholar
Prentice, J. R. and Anzar, M. (2010). Cryopreservation of mammalian oocyte for conservation of animal genetics. Veterinary Medicine International, 2011, 111. doi: 10.4061/2011/146405 CrossRefGoogle Scholar
Pukazhenthi, B. S., Nagashima, J., Travis, A. J., Costa, G. M., Escobar, E. N., França, L. R. and Wildt, D. E. (2015). Slow freezing, but not vitrification supports complete spermatogenesis in cryopreserved, neonatal sheep testicular xenografts. PLOS ONE, 10(4), e0123957. doi: 10.1371/journal.pone.0123957 CrossRefGoogle Scholar
Radaelli, M. R. M., Almodin, C. G., Minguetti-Câmara, V. C., Cerialli, P. M. A., Nassif, A. E. and Gonçalves, A. J. (2017). A comparison between a new vitrification protocol and the slow freezing method in the cryopreservation of prepubertal testicular tissue. JBRA Assisted Reproduction, 21(3), 188195. doi: 10.5935/1518-0557.20170037 CrossRefGoogle Scholar
Santos, R. R., Tharasanit, T., Van Haeften, T., Figueiredo, J. R., Silva, J. R. and Van den Hurk, R. (2007). Vitrification of goat preantral follicles enclosed in ovarian tissue by using conventional and solid-surface vitrification methods. Cell and Tissue Research, 327(1), 167176. doi: 10.1007/s00441-006-0240-2 CrossRefGoogle Scholar
Sum, A. K., Faller, R. and de Pablo, J. J. (2003). Molecular simulation study of phospholipid bilayers and insights of the interactions with disaccharides. Biophysical Journal, 85(5), 28302844. doi: 10.1016/s0006-3495(03)74706-7 CrossRefGoogle Scholar
Tian, T., Zhao, G., Han, D., Zhu, K., Chen, D., Zhang, Z., Wei, Z., Cao, Y. and Zhou, P. (2015). Effects of vitrification cryopreservation on follicular morphology and stress relaxation behaviors of human ovarian tissues: Sucrose versus trehalose as the non-permeable protective agent. Human Reproduction, 30(4), 877883. doi: 10.1093/humrep/dev012 CrossRefGoogle Scholar
Unni, S., Kasiviswanathan, S., D’Souza, S., Khavale, S., Mukherjee, S., Patwardhan, S. and Bhartiya, D. (2012). Efficient cryopreservation of testicular tissue: Effect of age, sample state, and concentration of cryoprotectant. Fertility and Sterility, 97(1), 200–8.e1. doi: 10.1016/j.fertnstert.2011.10.018 CrossRefGoogle Scholar
Xu, X.-R., Tan, F.-Q., Zhu, J.-Q., Ye, T., Wang, C.-L., Zhu, Y.-F., Dahms, H.-U., Jin, F. and Yang, W.-X. (2014). Detection of DNA damage caused by cryopreservation using a modified SCGE in large yellow croaker, Pseudosciaena crocea . Acta Biologica Hungarica, 65(4), 405413. doi: 10.1556/ABiol.65.2014.4.5 CrossRefGoogle Scholar
Zhang, X.-G., Wang, Y.-H., Han, C., Hu, S., Wang, L.-Q. and Hu, J.-H. (2015). Effects of trehalose supplementation on cell viability and oxidative stress variables in frozen–thawed bovine calf testicular tissue. Cryobiology, 70(3), 246252. doi: 10.1016/j.cryobiol.2015.03.004 CrossRefGoogle Scholar
Figure 0

Figure 1. Experimental design. Performance of testis fragment recovery tests for Steps 1 and 2 (1). Separation of experimental groups and control (2). Exposure of equilibrium solution (ES) and vitrification solution (VS), vitrification process and exposure to warming bath with warming solutions (3). Testis fragments after warming processing and analysis (4).

Figure 1

Figure 2. Germ and Sertoli cells are classified as intact, pyknotic or vacuolization (A). The blue line is the measure of total area, red line is the lumen area, larger and smaller diameters are represented for the yellow and orange lines, respectively (B). Scale bar represents 50 μm.

Figure 2

Table 1. Percentage of intact germ and Sertoli cells before and after cat testicular parenchyma vitrification

Figure 3

Figure 3. Histological sections of seminiferous tubules of domestic cat stained with haematoxylin and eosin (H&E). All analyses were made at ×400 magnification. Ethylene glycol (EG); dimethylsulfoxide (DMSO); sucrose (S), trehalose (T). Control group (C); EF + 0.1 M S (T1); EF + 0.5 M S (T2); EF + 0.1 M T (T3); EF + 0.5 M T (T4); EF + DMSO+0.1 M S (T5); EF + DMSO + 0.5 M S (T6); EF + DMSO + 0.1 M T (T7); EF + DMSO + 0.5 M T (T8). For Figure T1, the arrow shows normal spermatogonia after vitrification. For Figure T3, the arrow shows normal spermatocytes, and the arrowhead shows a normal Sertoli cell. For Figure T5, the arrow shows tubular basement membrane detachment. For Figure T7, the arrow shows normal spermatids. Scale bars represent 50 μm.

Figure 4

Table 2. Tubular measurements and epithelium height before and after testicular tissue vitrification of adult tomcats

Figure 5

Table 3. Score scale of cat testicular seminiferous tubules

Figure 6

Figure 4. Cell viability accessed by Hoechst-33342 stain and propidium iodide (PI) fluorescence dyes for EG groups at Step 2. (A) Tubular isolated cell emitting fluorescence by Hoechst-33342 stain. (B) Cat testicular cell emitting propidium iodide (PI) stain. (C) Graphic representation of isolated cell viability percentage before and after vitrification process. The columns show the mean and standard deviation of the mean of each experimental group. Sucrose (S); Trehalose (T). Scale bars represents = 50 μm. a–cDifferences indicate significant differences among treatments (P < 0.05).