Slow Freezing vs. Vitrification of Testicular Tissue in Nontraditional Animal Models

Abstract

Introduction:

Optimal cryopreservation of testicular tissue is essential for species research and conservation, enabling long-term storage of genetic resources through vitrification or slow freezing. Comparing responses from different taxonomic groups to these techniques is crucial for refining protocols and improving cryopreservation outcomes.

Objectives:

This study evaluated the effects of cryopreservation on cell viability, morphology, mitochondrial activity, and proliferative potential to optimize testicular tissue preservation strategies for wildlife conservation.

Methods:

We assessed testicular tissue from Felidae and Cervidae, including domestic cats (Felis catus) and Neotropical deer species, white-tailed deer (Odocoileus virginianus), Brazilian red brocket deer (Mazama nana), and gray brocket deer (Subulo gouazoubira). Experimental groups included control (no cryopreservation), slow freezing using Mr. Frosty or progressive temperature decrease, and conventional vitrification.

Results:

All methods preserved live cells and normal tissue morphology; however, compared with fresh tissue, cryopreservation significantly reduced tissue viability, mitochondrial membrane potential, and the proportion of intact seminiferous tubules. Species-specific differences emerged, with vitrification being most effective for domestic cats, while slow freezing yielded better results for Neotropical deer. Despite lower viability scores, vitrification could still be an acceptable option for cervids due to its rapid processing and minimal equipment requirements. In addition, post-cryopreservation tissue culture increased cell abnormalities, highlighting the need to optimize culture conditions for different species.

Conclusion:

This comparative study advances reproductive tissue preservation techniques and emphasizes the importance of tailored cryopreservation as well as in vitro culture protocols for diverse taxonomic groups.

Keywords

felids Cervidae deer cryobank cell viability wildlife conservation

Get full access to this article

View all access options for this article.

References

Comizzoli

, Holt

. Breakthroughs and new horizons in reproductive biology of rare and endangered animal species. Biol Reprod, 2019; 101(3):514–525.

Silva

, Lima

, Peixoto

, et al. Cryopreservation in mammalian conservation biology: Current applications and potential utility. RRBS, 2015; 4:1–8.

Ryder

, Onuma

. Viable cell culture banking for biodiversity characterization and conservation. Annu Rev Anim Biosci, 2018; 6:83–98.

Hobbs

, O’Brien

, Spindler

. Strategic gene banking for conservation. In: Scientific foundations of zoos and aquariums. ( Kaufman

, Bashaw

, Maple

., eds.) Cambridge University Press; 2019; pp. 112–146.

Mooney

, Ryder

, Houck

, et al. Maximizing the potential for living cell banks to contribute to global conservation priorities. Zoo Biol, 2023; 42(6):697–708.

Ballou

, Lacy

, Traylor-Holzer

, et al. Strategies for establishing and using genome resource banks to protect genetic diversity in conservation breeding programs. Zoo Biol, 2023; 42(2):175–184.

Kaneko

, Kikuchi

, Nakai

, et al. Generation of live piglets for the first time using sperm retrieved from immature testicular tissue cryopreserved and grafted into nude mice. PLoS One, 2013; 8(7):e70989.

Yokonishi

, Sato

, Komeya

, et al. Offspring production with sperm grown in vitro from cryopreserved testis tissues. Nat Commun, 2014; 5:4320.

González

, Duarte

JMB

. Speciation, evolutionary history and conservation trends of neotropical deer. Mastozool Neotrop, 2020; 27(SI)(0):35–46.

10.

Oliveira

, Vacari

, Duarte

JMB

. A method to freeze skin samples for cryobank: A test of some cryoprotectants for an endangered deer. Biopreserv Biobank, 2024; 22(3):211–216.

11.

Pukazhenthi

, Nagashima

, Travis

, et al. Slow freezing, but not vitrification, supports complete spermatogenesis in cryopreserved, neonatal sheep testicular xenografts. PLoS One, 2015; 10(4):e0123957.

12.

Pothana

, Devi

, Goel

. Cryopreservation of adult cervid testes. Cryobiology, 2017; 74:103–109.

13.

Chen

, Liu

, Hu

, et al. Cryopreservation of tissues and organs: Present, bottlenecks, and future. Front Vet Sci, 2023; 10:1201794.

14.

Wowk

. Thermodynamic aspects of vitrification. Cryobiology, 2010; 60(1):11–22.

15.

Lima

DBC

, Silva

TFP

, Aquino-Cortez

, et al. Vitrification of testicular tissue from prepubertal cats in cryotubes using different cryoprotectant associations. Theriogenology, 2018; 110:110–115.

16.

Thuwanut

, Chatdarong

. Cryopreservation of cat testicular tissues: Effects of storage temperature, freezing protocols and cryoprotective agents. Reprod Domest Anim, 2012; 47(5):777–781.

17.

Dumont

, Arkoun

, Jumeau

, et al. Assessment of the optimal vitrification protocol for pre-pubertal mice testes leading to successful in vitro production of flagellated spermatozoa. Andrology, 2015; 3(3):611–625.

18.

Lima

DBC

, Silva

LDM

, Comizzoli

. Influence of warming and reanimation conditions on seminiferous tubule morphology, mitochondrial activity, and cell composition of vitrified testicular tissues in the domestic cat model. PLoS One, 2018; 13(11):e0207317.

19.

Wang

, Xiao

, Li

, et al. Novel needle immersed vitrification: A pratical and convenient method with potential advantages in mouse sand human ovarian tissue cryopreservation. Hum Reprod, 2008; 23(10):2256–2265.

20.

Peris-Frau

, Benito-Blanco

, Martínez-Nevado

, et al. DNA integrity and viability of testicular cells from diverse wild species after slow freezing or vitrification. Front Vet Sci, 2022; 9:1114695.

21.

Ake-Lopez

, Cavazos-Arizpe

, Magana-Monforte

, et al. Effect of age and postmortem time on some white-tailed deer (Odocoileus virginianus texanus) epididymal sperm characteristics. Am J Animal Veterinary Sci, 2010; 5(3):183–186.

22.

Lima

DBC

, Silva

TFP

, Morais

, et al. Different associations of cryoprotectants for testicular tissue of prepubertal cat submitted to vitrification. Reprod Domest Anim, 2017; 52(Suppl 2):235–241.

23.

Silva

, Bezerra

LGP

, Praxedes

ECG

, et al. Combination of intracellular cryoprotectants preserves the structure and cells’ proliferative capacity of adult collared peccary testicular tissue subjected to solid surface vitrification. Cryobiology, 2019; 91:53–60.

24.

Silva

, Pereira

, Brasil

, et al. Influence of freezing techniques and glycerol-based cryoprotectant combinations on the survival of testicular tissues from adult collared peccaries. Theriogenology, 2021; 167:111–119.

25.

Silva

HVR

, da Silva

, Lee

, et al. Influence of microwave-assisted drying on structural integrity and viability of testicular tissues from adult and prepubertal domestic cats. Biopreserv Biobank., 2020; 18(5):415–424.

26.

Faure

, Bouty

, O’Brien

, et al. Testicular biopsy in prepubertal boys: A worthwhile minor surgical procedure? Nat Rev Urol, 2016; 13(3):141–150.

27.

Milazzo

, Vaudreuil

, Cauliez

, et al. Comparison of conditions for cryopreservation of testicular tissue from immature mice. Hum Reprod, 2008; 23(1):17–28.

28.

Borges

, Lira

GPO

, Nascimento

, et al. Influence of cryopreservation solution on the in vitro culture of skin tissues derived from collared peccary (Pecari tajacu Linnaeus, 1758). Biopreserv Biobank, 2018; 16(2):77–81.

29.

Chacur

MGM

, Ibrahim

, Arrebola

TAH

, et al. Evaluation of the AgNOR staining method in ovine testicles. Arq Bras Med Vet Zootec, 2015; 67(2):447–454.

30.

, Liu

, Wang

, et al. The role of PGC-1α and MRP1 in lead-induced mitochondrial toxicity in testicular Sertoli cells. Toxicology, 2016; 355–356:39–48.

31.

Praxedes

ECG

, Peixoto

GCX

, Silva

, et al. Reproduction in agouti (Dasyprocta spp.): A review of reproductive physiology for developing assisted reproductive techniques. Anim Reprod, 2018; 15(4):1181–1192.

32.

Travers

, Arkoun

, Safsaf

, et al. Effects of vitamin A on in vitro maturation of pre-pubertal mouse spermatogonial stem cells. PLoS One, 2013; 8(12):e82819.

33.

Amelkina

, Silva

, et al. Transcriptome dynamics in developing testes of domestic cats and impact of age on tissue resilience to cryopreservation. BMC Genet, 2021; 22(1):847.

34.

Thuwanut

, Srisuwatanasagul

, Wongbandue

, et al. Sperm quality and the morphology of cryopreserved testicular tissues recovered post-mortem from diverse wild species. Cryobiology, 2013; 67(2):244–247.

35.

Nabi

, Khalili

, Halvaei

, et al. Prolonged incubation of processed human spermatozoa will increase DNA fragmentation. Andrologia, 2014; 46(4):374–379.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

1.73 MB

0.00 MB

0.01 MB

3.01 MB