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Evaluation of sperm and hormonal assessments in Wagyu, Nellore, and Angus bulls

Published online by Cambridge University Press:  26 July 2023

A. R. Moura
Affiliation:
Center for Natural and Human Sciences, Federal University of ABC, Santo André, Sao Paulo, Brazil
A. R. Santos Jr
Affiliation:
Center for Natural and Human Sciences, Federal University of ABC, Santo André, Sao Paulo, Brazil
J. D. A. Losano
Affiliation:
Department of Animal Sciences, University of Florida, USA Department of Animal Reproduction, School of Veterinary Medicine and Animal Science, University of Sao Paulo, Sao Paulo, Brazil
A. F. P. Siqueira
Affiliation:
Department of Animal Reproduction, School of Veterinary Medicine and Animal Science, University of Sao Paulo, Sao Paulo, Brazil
T. R. S. Hamilton
Affiliation:
Department of Animal Reproduction, School of Veterinary Medicine and Animal Science, University of Sao Paulo, Sao Paulo, Brazil
R. Zanella
Affiliation:
Escola de Ciências Agrárias Inovação e Negócios, Curso de Medicina Veterinária, Universidade de Passo Fundo, Passo Fundo, Rio Grande do Sul, Brazil Programa de Pós Graduação em BioExperimentação, Universidade de Passo Fundo, Passo Fundo, Rio Grande do Sul, Brazil
K. C. Caires
Affiliation:
Department of Human Nutrition, Food and Animal Sciences, University of Hawaii, Manoa, Hawaii, USA
R. Simões*
Affiliation:
Center for Natural and Human Sciences, Federal University of ABC, Santo André, Sao Paulo, Brazil
*
Corresponding author: Renata Simões; Email: [email protected]
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Summary

Wagyu bulls are known to have a highly exacerbated libido, as shown by the intense sexual interest of young calves. Therefore we believe that Wagyu male animals have specialized Sertoli and Leydig cells that are directly involved with the sexual precocity in this breed as mature bulls have a small scrotal circumference. This study aimed to evaluate whether there were differences in the hormone and sperm characteristics of Wagyu bulls compared with the same characteristics of subspecies Bos indicus and Bos taurus sires. Frozen–thawed semen from Wagyu, Nellore, and Angus sires were analyzed for sperm kinetics (computer-assisted sperm analysis), plasma membrane integrity, chromatin integrity, acrosome status, mitochondrial activity, lipid peroxidation and hormone [luteinizing hormone (LH) and testosterone] serum concentration. The results showed that Wagyu had lower total motility and an increased number of sperm with no motility when compared with Nellore and Angus bulls. Wagyu breed did not differ from those breeds when considering plasma and acrosome membranes integrity, mitochondrial potential, chromatin resistance, sperm lipid peroxidation or hormone (LH and testosterone) concentrations. We concluded that Wagyu sires had lower total motility when compared with Nellore and Angus bulls. Wagyu breed did not differ from these breeds when considering plasma and acrosome membranes integrity, mitochondrial potential, chromatin resistance, sperm lipid peroxidation, or hormone (LH and testosterone) concentrations.

Type
Research Article
Copyright
© Federal University of the ABC and the Author(s), 2023. Published by Cambridge University Press

Introduction

Brazil is the world’s second-largest producer of beef with a herd of 218.2 million animals. Notably, Brazil has become the world’s largest beef exporter, exporting 2.69 million tons of bovine carcass weight, a trade worth more than US$8.4 billion in 2021 (IBGE, 2017; De Nadai Fernandes et al., Reference De Nadai Fernandes, Sarriés, Bacchi, Mazola, Gonzaga and Sarriés2020; Zu Ermgassen et al., Reference Zu Ermgassen, Godar, Lathuillière, Löfgren, Gardner, Vasconcelos and Meyfroidt2020; ABIEC, 2021). Roughly 80% of the Brazilian herd is composed of Zebu cattle (Bos taurus indicus), mainly the Nellore breed. The other 20% are European breeds (Bos taurus taurus), especially the Angus breed and more recently the Wagyu breed (Rodrigues et al., Reference Rodrigues, Chizzotti, Vital, Baracat-Pereira, Barros, Busato, Gomes, Ladeira and Martins2017; Rezende-de-Souza et al., Reference Rezende-de-Souza, Cardello, de Paula, Ribeiro, Calkins and Pflanzer2021).

Consumers have become more careful with the quality of food in general, especially with the quality of meat and how it can directly influence health. In this sense, in Brazil, the high demand for special meats has directed enterprises, such as slaughterhouses, meat shops, or restaurants, to produce high-quality meat. The increased intramuscular or marbling fat content is correlated to juiciness, tenderness, and meat flavour. Wagyu adds value from the marbling process as Wagyu has a high propensity to accumulate intramuscular fat. Furthermore, the fatty acid composition of lipids in meat is also important for human health and, therefore, this subject has been extensively studied in recent years (Radunz et al., Reference Radunz, Loerch, Lowe, Fluharty and Zerby2009; Ladeira et al., Reference Ladeira, Schoonmaker, Swanson, Duckett, Gionbelli, Rodrigues and Teixeira2018; Connolly et al., Reference Connolly, Dona, Hamblin, D’Occhio and González2020; Facioli et al., Reference Facioli, De Marchi, Marques, Michelon, Zanella, Caires, Reeves and Zanella2020).

Animal reproduction is fundamental for addressing the growing demand for access to animal proteins. Therefore, this leads farmers to be as efficient as possible in the breeding and management of livestock (Yánez-Ortiz et al., Reference Yánez-Ortiz, Catalán, Rodríguez-Gil, Miró and Yeste2022). To increase reproductive capacity, bulls must produce morphologically normal and large numbers of sperm (Teixeira et al., Reference Teixeira, Coelho, Tomich, Pacheco Rodrigues, Camρos, Machado, Gualberto Barbosa da Silva, Monteiro and Ribeiro Pereira2019). In this context, a detailed breeding soundness evaluation (BSE) of the bull should be carried out to assess the sire’s reproductive health (Silva et al., Reference Silva, Pedrosa, Silva, Eler, Guimarães and Albuquerque2011; Romanello et al., Reference Romanello, de Brito Lourenço Junior, Barioni Junior, Brandão, Marcondes, Pezzopane, de Andrade Pantoja, Botta, Giro, Moura, do Nascimento Barreto and Garcia2018; Rodrigues et al., Reference Rodrigues, Rossi, Vrisman, Taira, Souza, Zorzetto, Bastos, de Paz, de Lima, Monteiro and Franco Oliveira2020; Leite et al., Reference Leite, de Agostini Losano, de Souza Ramos Angrimani, Sousa, de Miranda Alves, Cavallin, Kawai, Cortada, Zuge and Nichi2021).

Nonetheless, Wagyu bulls have a higher libido, higher levels of testosterone and sperm production when compared with other taurine and indicine breeds (Smith-Thomas, pers. commun.; Sosa et al., Reference Sosa, Senger and Reeves2002; Tatman et al., Reference Tatman, Chase, Wilson, Neuendorff, Lewis, Brown and Randel2022). The purpose of this study was to evaluate whether there were differences in the hormone and sperm characteristics of Wagyu bulls compared with the same characteristics of subspecies Bos indicus and Bos taurus sires. Wagyu bulls are known to have a highly exacerbated libido, as shown by the intense sexual interest of young calves. Therefore we believe that Wagyu male animals have specialized Sertoli and Leydig cells that are directly involved with the sexual precocity in this breed as mature animals have a small scrotal circumference that can affect sperm production (Sosa et al., Reference Sosa, Senger and Reeves2002).

Materials and methods

Experimental procedures adopted by this study are in agreement with the Principles of Ethics in Animal Research adopted by the Commission of Bioethics, Federal University of ABC (UFABC, protocol # 8993100516). This study was partially supported by Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES).

Experimental design

Before starting the experiment, we performed a power analysis using PROC POWER (SAS System for Windows 9.3) to determine the minimal number of experimental units for each group. We considered only the variable motility. A result above 0.8 indicated that five experimental units per group would be adequate for the experiment, ensuring a high probability of observing the effect of treatments. Therefore, the experimental design was performed with five animals per group; each breed was considered as an experimental group: Angus, Nellore, and Wagyu.

Semen batches from Nellore and Angus bulls were donated from a commercial artificial insemination centre in Brazil (Seleon Biotechnology, Itatinga, SP, Brazil). Semen batches from Wagyu bulls were donated from a breeding herd located in the state of Rio Grande do Sul, Brazil. Data regarding sperm analysis before cryopreservation were not available for this study. However, all samples from all three breeds were diluted to a concentration of 25 million sperm cells/straw for cryopreservation. The cryopreservation procedure was performed according to local standard protocols and both used egg yolk-based extenders.

All semen samples were submitted to evaluate sperm motility using computer-assisted sperm analysis (CASA), acrosome integrity (Pisum sativum agglutinin; FITC-PSA), plasma membrane integrity (propidium iodide; PI), mitochondrial membrane potential (5,5′,6,6′-tetrachloro-1,1′,3,3′-tetraethyl-benzimidazolylcarbocyanine iodide; JC-1), and chromatin resistance using flow cytometry and oxidative stress by thiobarbituric acid reactive substances assay (TBARS). Blood samples were used to evaluate testosterone and luteinizing hormone (LH).

Semen preparation

Semen straws were thawed at 37ºC for 30 s. To remove the extender and recover sperm cells, 250 µl of semen were centrifuged at room temperature for 6 min at 9000 g in FertTALP warmed at 38.5°C (Parrish et al., Reference Parrish, Susko-Parrish, Winer and First1988) with no capacitation inductors. Sperm cells were recovered and washed again in FertTALP medium for 3 min at 9000 g. The sperm samples were then evaluated for acrosome integrity, membrane integrity, mitochondrial membrane potential, sperm chromatin status, and lipid peroxidation.

Assessment of sperm kinetics

Sperm motility was evaluated using CASA (Hamilton-Thorne, HTR Ceros 12.3, USA) as described by Leite et al. (Reference Leite, Losano, Kawai, Rui, Nagai, Castiglioni, Siqueira, D’Avila Assumpção, Baruselli and Nichi2022) elsewhere. Briefly, 7 µl of each sample were placed between a Leja counting chamber (Orange Medical, Brussels, Belgium) previously heated to 37°C. A minimum of five randomly selected microscopic fields per sample was analyzed. The following variables were considered: total motility (MOT; %), progressive motility (PROG; %), average path velocity (VAP; µm/s), straight-line velocity (VSL; µm/s), curvilinear velocity (VCL; µm/s), amplitude of lateral head displacement (ALH; µm), beat cross-frequency (BCF; Hz), straightness (STR, VSL/VAP; %), and linearity (LIN; %). Sperm cells were also classified based on velocity: (1) rapid (RAP, VAP > 50 µm/s, %); (2) medium (MED, 30 µm/s < VAP < 50 µm/s, %); slow (SLOW, VAP < 30 µm/s or VSL < 15 µm/s, %); or (4) static (STATIC, %). The setup for sperm kinetic analysis was 60 Hz frames/s for image acquisition, with a minimum of 80 cells per field, minimum cell size of 5 pixels, 70 for cell intensity, path velocity of 50 µm/s and STR of 70% for progressive cells; and VAP and VSL cutoff at 30 and 15 µm/s for slow cells.

Acrosome integrity, membrane integrity, mitochondrial membrane potential, and sperm chromatin status evaluation

Acrosome integrity, membrane integrity, mitochondrial membrane potential, and sperm chromatin status were evaluated as described by Siqueira et al. (Reference Siqueira, de Castro, de Assis, Bicudo, Mendes, Nichi, Visintin and Assumpção2018). Evaluations were performed using flow cytometry (Guava EasyCyte™, Guava® Technologies, Hayward, CA, USA) equipped with a 20 mW 488 nm argon excitation laser. Probes were purchased from Sigma and Molecular Probes.

Cytometry data were analyzed using the FlowJo software (version 10.2 Flow Cytometry Analysis Software–Tree Star Inc., Ashland, Oregon, USA). In total, 20,000 events per sample were analyzed. Cells were identified and selected excluding debris, probes particles and non-single sperm events, applying a gate on forward scatter (FSC) versus green fluorescence dot plot (log mode) around the single sperm events to acrosome, membrane, and mitochondrial analysis. For chromatin analysis, the single sperm events were selected by applying a gate on forward scatter (FSC) versus red fluorescence dot plot (log mode).

Simultaneously, a staining protocol was performed by incubating 187,500 cells for 5 min with 6 μM of propidium iodide (PI) associated with 5 μg of fluorescein-conjugated Pisum sativum (FITC-PSA). PI emits red fluorescence for damaged plasma membrane, while FITC-PSA emits green fluorescence for damaged acrosome. Mitochondrial membrane potential was analyzed by incubating 187,500 cells for 5 min with 1 μM of tetraethylbenzimidazolycarbocyanine iodide (JC-1) that emits green fluorescence for low mitochondrial potential and red/orange fluorescence for high mitochondrial potential.

As a positive control for damaged acrosome and membrane, and lack of mitochondrial membrane potential, a sample was prepared as described by Siqueira et al. (Reference Siqueira, de Castro, de Assis, Bicudo, Mendes, Nichi, Visintin and Assumpção2018). Briefly, a sperm sample was submitted to freezing/thawing cycles (1 min in liquid nitrogen/1 min in a water bath at 60°C, five times). As a negative control, one sample was prepared as described above for experimental samples.

Chromatin sperm analysis was performed according to Simões et al. (Reference Simões, Feitosa, Siqueira, Nichi, Paula-Lopes, Marques, Peres, Barnabe, Visintin and Assumpção2013) with some modifications. Briefly, 375,000 sperm cells were added to 50 μl TNE buffer (10 mM Tris−HCl, 0.15 M NaCl, 1 mM EDTA disodium pH 7.4) and 100 μl of acid detergent solution [0.08 M HCl, 0.15 M NaCl, 0.1% (v/v) Triton X-100, pH 1.4]. After 30 s, 300 μl of acridine orange solution (6 μg/ml in 0.1 M citric acid, 0.2 M Na2HPO4, 1 mM de EDTA, 0.15 M NaCl, pH 6.0) were added, and an evaluation was performed using flow cytometry at 3–5 min following acridine orange solution addition. As a control of chromatin damage, a sample was incubated with HCl (1.2 M in acid detergent solution, pH 0.1) for 1 min. As a control of chromatin resistance, a sample was prepared as described above for the experimental samples.

To calculate the determination coefficient of cytometry analyses, a positive (100%) and a negative control (0%) for each analysis were evaluated individually and mixed in different proportions: 1:3 (25%); 1:1 (50%); 3:1 (75%). Negative and positive thresholds and gates for each analysis were set up to achieve the highest determination coefficient on controls and proportions analysis. All traits analysis reached coefficients higher than 0.94. Compensation parameters and gates applied were held for all samples. Dot plots showing rectangular gates applied to select single sperm events and histograms showing bisector gates applied to separate negative and positive events are presented as Supplementary Material (Figures S1S4). We presented graphs of negative and positive controls, along with their respective mixtures from each probe analyzed.

Sperm lipid peroxidation assessment

Sperm susceptibility to lipid peroxidation was evaluated by the TBARS assay. The TBARS reaction evaluates malondialdehyde (MDA) concentrations as products of lipid peroxidation. Thiobarbituric acid reacts with MDA to produce a pink-coloured complex.

This analysis was performed as described by Ohkawa et al. (Reference Ohkawa, Ohishi and Yagi1979) and adapted by Nichi et al. (Reference Nichi, Bols, Züge, Barnabe, Goovaerts, Barnabe and Cortada2006). In summary, lipid peroxidation was induced by adding ferrous sulfate (100 μl, 4 mM) and sodium ascorbate (100 μl, 20 mM) to 400 μl of the sperm suspension (2.5 × 106 sperms/ml). The mixture was then incubated for 90 min at 37°C. Subsequently, ice-cold 10% trichloroacetic acid (TCA; ratio 2:1) were added. Samples were then centrifuged (18000 g, 10 min, 5°C) to precipitate the protein. The supernatant was mixed with 1% thiobarbituric acid (TBA, ratio 1:1) in a cryotube vial. Samples were placed into a boiling water bath (100°C) for 15 min and then immediately cooled in an ice bath (0°C) to stop the chemical reaction. The TBARS were then quantified using a spectrophotometer (UV–vis spectrophotometer, Ultrospec 3300 Pro, Biochrom Ltd, Cambridge, UK) at a wavelength of 532 nm. The lipid peroxidation index was described as nanograms of TBARS/106 sperm.

Blood samples and hormonal assay

Blood samples (10 ml) were collected from a jugular vein into centrifuge vacuum tubes containing heparin. Blood tubes were centrifuged at 3000 g for 20 min. Plasma samples were stored individually at −20°C until further analysis.

Plasma LH was evaluated as previously described by Bolt and Rollins (Reference Bolt and Rollins1983) and Bolt et al. (Reference Bolt, Scott and Kiracofe1990). Plasma LH concentrations were measured by double-antibody radioimmunoassay (RIA) using purified bovine LH standards. A highly purified LH (AFP8614B; National Hormone and Pituitary Programme) was used for both the iodinated tracer and reference standard preparation. The intra-assay coefficients of variation (high and low) and the sensitivity for LH were 9.15%, 5.97% and 0.0373 ng/ml, respectively. Testosterone concentration was determined by an RIA using a commercial kit RIA Testosterone, direct (Beckman Coulter, Prague, Czech Republic) according to the manufacturer’s instructions.

Statistical analysis

Statistical Analysis System 9.3 (SAS Institute, Cary, NC) was used to analyze the dependent variables. All data were tested for normality of residues and homogeneity of variances. Variables that did not comply with these statistical premises were transformed (logarithmic transformation was used to evaluate the chromatin susceptibility; testosterone quantification; percentage of sperm with damaged acrosome and intact membrane; percentage of sperm with static movement; and intracellular lipid peroxidation; square root transformation was used to evaluate the percentage of sperm with damaged plasma and acrosome membranes; and the inverse of the data was used to evaluate the percentage of sperm with medium movement). The general linear models (GLM) procedure was used to evaluate the breed effect (Angus, Nellore, and Wagyu). Comparisons of means were performed using the Duncan Test. A 5% significance level was used to reject the null hypothesis. The results are presented as mean ± standard error of the mean (SEM).

Results

Assessment of sperm kinetics

Unfortunately, two Wagyu bulls presented difficulties during semen collection compromising the sperm processing, therefore the Wagyu group was formed with only three experimental units.

The results corresponding to sperm kinetics from Angus, Nellore, and Wagyu bulls are shown in Figure 1. Sperm from Nellore bulls showed greater amplitude of lateral head displacement (ALH) when compared with Wagyu and Angus bulls (P = 0.016; Figure 1a). However, Wagyu bulls showed no significant difference for the same parameter when compared with Angus bulls. Considering the variable STR, sperm from Wagyu bulls showed higher straightness (STR) cells when compared with Nellore bulls (P = 0.032; Figure 1b). However, Angus bulls showed no significant difference for the same parameter when compared with Nellore and Wagyu bulls.

Figure 1. Mean ± standard error of the mean (SEM) of sperm kinetic analysis by computer-assisted sperm analysis (CASA). (a) Amplitude of lateral head displacement (ALH; µm). (b) Straightness (STR, VSL/VAP; %). (c) Linearity (LIN; %). (d) Total motility (MOT; %). (e) Medium movement (MEDIUM; %). (f) Static sperm (STATIC; %) in semen samples of Angus (n = 5), Nellore (n = 5) and Wagyu (n = 3) bull. Different superscript letters represent significant statistical differences (P < 0.05).

When evaluating linearity (LIN), Nellore bulls showed cells with lower LIN than Wagyu and Angus bulls (P = 0.016; Figure 1c). Angus and Wagyu sires did not show significant differences for LIN. Still, Wagyu bulls showed sperm with lower total motility (MOT) when compared with Nellore and Angus bulls (P = 0.012; Figure 1d). Conversely, Angus and Nellore bulls showed no significant difference for MOT. Wagyu sires showed sperm cells with lower medium movement (MEDIUM) than Angus and Nellore bulls (P = 0.004; Figure 1e). However, Angus bulls showed no significant difference for the same parameter when compared with Nellore bulls. Finally, sperm from Wagyu bulls had a higher percentage of static sperm (STATIC) when compared with Nellore and Angus bulls (P = 0.022; Figure 1f). Angus bulls showed no significant difference for the same parameter when compared with Nellore bulls.

Acrosome integrity, membrane integrity, mitochondrial membrane potential, and sperm chromatin status evaluation

The results corresponding to acrosome integrity, plasma membrane integrity, mitochondrial membrane potential, and sperm chromatin status evaluations from Wagyu, Nellore, and Angus bulls are shown on Table 1. Spermatozoa from the three bull breeds (Nellore, Wagyu and Angus) showed no significant difference in terms of sperm chromatin structure assay (SCSA) quality (P = 0.903), high mitochondrial membrane potential (HIGH JC-1; P = 0.753). Nellore, Wagyu, and Angus bulls did not show significant differences in terms of sperm cells with damaged acrosome and intact plasma membrane (FITC–PI+/−; P = 0.900); number of sperm cells with damaged acrosome and plasma membrane (FITC–PI+/+ ; P = 0.146); number of sperm cells with intact acrosome and damaged plasma membrane (FITC–PI−/+; P = 0.860); and amount of sperm cells with intact acrosome and plasma membrane (FITC–PI−/−; P = 0.625).

Table 1. Mean ± standard error of the mean (SEM) and probability (P) of sperm chromatin structure (SCSA), mitochondrial membrane potential (JC-1), acrosome and plasma membrane integrities (FITC–PI) and sperm lipid peroxidation status evaluated by induced thiobarbituric acid reactive substances (TBARS) assay among Angus (n = 5), Nellore (n = 5) and Wagyu (n = 3) bulls

SCSA+ = intact sperm chromatin; JC-1 HIGH = high mitochondrial membrane potential; FITC–PI (+/−) = damaged acrosome and intact plasma membrane; FITC–PI (+/+) = damaged plasma and acrosome membranes; FITC–PI (−/+) = intact acrosome and damaged plasma membrane; FITC–PI (−/−) = intact plasma and acrosome membranes; TBARS = induced thiobarbituric acid reactive substances (ng TBARS/106 sperm).

Sperm lipid peroxidation assessment

The results corresponding to sperm cell lipid peroxidation status from Wagyu, Nellore, and Angus sires are shown in Table 1. Spermatozoa from the three bull breeds (Nellore, Wagyu, and Angus) showed no significant difference (P = 0.646) in terms of sperm lipid peroxidation status.

Hormonal assay

The results corresponding to serum testosterone and LH concentrations from Wagyu, Nellore, and Angus sires are shown in Table 2. Spermatozoa from the three bull breeds (Nellore, Wagyu and Angus) showed no significant difference (P = 0.384) in terms of serum testosterone and LH concentrations.

Table 2. Mean ± standard error of the mean (SEM) and probability (P) of serum testosterone and luteinizing hormone (LH) concentrations among Angus (n = 5), Nellore (n = 5) and Wagyu (n = 3) bulls

Discussion

Sire fertility is extremely important for reproduction in several species, including cattle. After the introduction of artificial insemination (AI) practice and increasing worldwide export of semen straws, sperm analysis became even more substantial (Amann and Waberski, Reference Amann and Waberski2014; Nagy et al., Reference Nagy, Polichronopoulos, Gáspárdy, Solti and Cseh2015; Leite et al., Reference Leite, Losano, Kawai, Rui, Nagai, Castiglioni, Siqueira, D’Avila Assumpção, Baruselli and Nichi2022; O’Meara et al., Reference O’Meara, Henrotte, Kupisiewicz, Latour, Broekhuijse, Camus, Gavin-Plagne and Sellem2022). Motility is one of the most important seminal parameters associated with the sperm fertilizing ability and it may indicate spermatozoa viability and structural integrity (Kathiravan et al., Reference Kathiravan, Kalatharan, Karthikeya, Rengarajan and Kadirvel2011; Nagy et al., Reference Nagy, Polichronopoulos, Gáspárdy, Solti and Cseh2015; Singh et al., Reference Singh, Kumar and Bisla2021; Leite et al., Reference Leite, Losano, Kawai, Rui, Nagai, Castiglioni, Siqueira, D’Avila Assumpção, Baruselli and Nichi2022). Conventional semen analysis (semen volume, colour, density, viscosity, and sperm motility, vigour, concentration and morphology) is an important and also a practical and low-cost evaluation to identify sperm quality. However, as sperm cells are highly specialized cells, conventional analysis is not sufficient to evaluate sperm function and fertilization ability (Perumal et al., Reference Perumal, Srivastava, Ghosh and Baruah2014; Nagy et al., Reference Nagy, Polichronopoulos, Gáspárdy, Solti and Cseh2015; Leite et al., Reference Leite, Losano, Kawai, Rui, Nagai, Castiglioni, Siqueira, D’Avila Assumpção, Baruselli and Nichi2022; O’Meara et al., Reference O’Meara, Henrotte, Kupisiewicz, Latour, Broekhuijse, Camus, Gavin-Plagne and Sellem2022). There is a large variation among laboratories and even within each or between technicians. According to Brazil et al. (Reference Brazil, Swan, Tollner, Treece, Drobnis, Wang, Redmon and Overstreet2004) the variation coefficient among laboratories is ∼23–73% for sperm concentration, 9–37% for sperm motility and 25–87% for sperm morphology evaluation.

To overcome the operator dependency of conventional semen analysis, technologies have been developed. CASA is a computer system equipped with a high-resolution camera and microscope that allows a more accurate sperm motion evaluation. Moreover, CASA allows the reduction in bias compared with visual evaluations (Kathiravan et al., Reference Kathiravan, Kalatharan, Karthikeya, Rengarajan and Kadirvel2011; Amann and Waberski, Reference Amann and Waberski2014; Nagy et al., Reference Nagy, Polichronopoulos, Gáspárdy, Solti and Cseh2015; Valverde et al., Reference Valverde, Barquero and Soler2020; Fernandez-Novo et al., Reference Fernandez-Novo, Santos-Lopez, Barrajon-Masa, Mozas, de Mercado, Caceres, Garrafa, Gonzalez-Martin, Perez-Villalobos, Oliet, Astiz and Perez-Garnelo2021). The results for sperm kinetics analyses in the present study indicated that the Nellore bulls showed the highest head displacement amplitude (ALH) compared with Angus and Wagyu sires. Still, Wagyu and Angus bulls, despite showing lower ALH values, did not show a significant difference between them. The sperm cells with higher ALH indicated a higher ability to penetrate cervical mucus and fuse with the zona pellucida of the oocyte. It is believed that the higher the ALH, the greater the chance of fertilizing the female gamete (Perumal et al., Reference Perumal, Srivastava, Ghosh and Baruah2014).

The STR and LIN parameters are related to the straightness of the sperm’s movement and ability to migrate in cervical mucus (Goovaerts et al., Reference Goovaerts, Hoflack, Van Soom, Dewulf, Nichi, de Kruif and Bols2006; Robayo et al., Reference Robayo, Montenegro, Valdés and Cox2008; Kathiravan et al., Reference Kathiravan, Kalatharan, Karthikeya, Rengarajan and Kadirvel2011; Perumal et al., Reference Perumal, Srivastava, Ghosh and Baruah2014). The results of sperm kinetics analysis in the present study indicated that the Wagyu sires showed higher values for both parameters when compared with Angus and Nellore bulls. However, the STR from Wagyu bulls sperm cells was not significantly different from Angus bulls. Conversely, the STR of Angus bulls was not significantly different from Nellore bulls. Regarding linearity (LIN), the Angus bulls had the best results when compared with Nellore bulls, but did not differ significantly when compared with the LIN of the Wagyu bulls. High ALH and low STR values are characteristic of hyperactive spermatozoa. Conversely, high values of LIN and STR indicated a progressive movement pattern of sperm cells (Ratnawati and Luthfi, Reference Ratnawati and Luthfi2020). Considering all this together, it seems that sperm cells from Nellore sires that showed higher ALH and lower STR and LIN had started the capacitation process before Angus and Wagyu. Still, Wagyu spermatozoa are more capable of swimming in a straight line.

Considering total motility (MOT) and not motile (STATIC) cells, it was observed that Wagyu sires showed lower MOT than Angus and Nellore bulls and a higher number of STATIC cells. Despite having a straighter pattern than Nellore and Angus bulls, Wagyu sperm were slower. Some might think that these characteristics of sperm kinetics in Wagyu sires may be worrying, as the bovine oocyte after being ovulated remains viable in the fallopian tube for an average of 6–8 h (Miller, Reference Miller2018). In other words, fertilization of aged oocytes produces poorer quality embryos. Notwithstanding, another possible hypothesis that could explain lower motility is the sperm freezing procedure. According to Siqueira et al. (Reference Siqueira, de Castro, de Assis, Bicudo, Mendes, Nichi, Visintin and Assumpção2018) and Kathiravan et al. (Reference Kathiravan, Kalatharan, Karthikeya, Rengarajan and Kadirvel2011), sperm cells that survive suboptimal conditions during the cryopreservation process are more resistant to in vitro conditions, showing higher longevity after thawing, indicating that those spermatozoa may be more prone to fertilize the oocyte, even though they were less motile. Yet, sperm motion characteristics seem to be of minor importance, as the uterine contractions may be of greater consequence (Kunz et al., Reference Kunz, Beil, Deiniger, Einspanier, Mall and Leyendecker1997) or when considering IVP conditions in which samples are submitted to motile sperm selection techniques as density gradient centrifugation overcoming lower initial motility.

Differences in sperm kinetics evaluation among sires may be due to differences in the genetic group of animals (Hoflack et al., Reference Hoflack, Opsomer, Rijsselaere, Van Soom, Maes, de Kruif and Duchateau2007; Kathiravan et al., Reference Kathiravan, Kalatharan, Edwin and Veerapandian2008; Morrell et al., Reference Morrell, Valeanu, Lundeheim and Johannisson2018). Detailed studies, however, must be conducted to more accurately determine the associations among values for sperm kinetics and those for fertility variables. Conversely, a higher ALH and lower STR and LIN as observed in Nellore bulls may not be good sperm traits to be considered as biomarkers. Sperm hyperactivation alters sperm swimming patterns, increasing ALH and decreasing LIN values (Shi and Roldan, Reference Shi and Roldan1995; Sansegundo et al., Reference Sansegundo, Tourmente and Roldan2022). It seems reasonable to hypothesize that higher hyperactivated sperm cells as seen in Nellore bulls in the present study may be related to a premature event that leads to higher energy consumption and ATP decrease more rapidly. This situation could diminish fertilization rates in Nellore sires when compared with Angus and Wagyu. However, more studies are needed to confirm this hypothesis.

As fertilization is a complex and multistep process, it is unlikely that only one sperm attribute could be considered a fertility biomarker (Oliveira et al., Reference Oliveira, de Arruda, de Andrade, Celeghini, Reeb, Martins, dos Santos, Beletti, Peres, Monteiro and Hossepian de Lima2013). Therefore, it is important to evaluate a wide range of sperm features to identify potential biomarkers for bull fertility (Utt, Reference Utt2016). In addition to sperm motility, the evaluation of sperm function attributes such as acrosomal and plasma membrane integrity, chromatin status and mitochondrial activity remains one of the keystones in semen laboratory analysis (Simões et al., Reference Simões, Feitosa, Siqueira, Nichi, Paula-Lopes, Marques, Peres, Barnabe, Visintin and Assumpção2013; Malama et al., Reference Malama, Zeron, Janett, Siuda, Roth and Bollwein2017; Bernecic et al., Reference Bernecic, Donnellan, O’Callaghan, Kupisiewicz, O’Meara, Weldon, Lonergan, Kenny and Fair2021). IVP is a useful tool to compare in vitro fertility of samples from bulls and breeds under certain conditions. Nevertheless, until now, no single assay has been able to accurately predict bull fertility.

In Angus sires it was shown that 82% of in vitro fertilization rates may vary according to sperm features such as sperm morphology, acrosome and plasma membrane integrities (Tartaglione and Ritta, Reference Tartaglione and Ritta2004). In Holstein Friesian bulls, Bernecic et al. (Reference Bernecic, Donnellan, O’Callaghan, Kupisiewicz, O’Meara, Weldon, Lonergan, Kenny and Fair2021) developed a linear and logistic predictive model to evaluate bull fertility. According to the authors, 47% of bull fertility variation is due to plasma membrane changes and 90% to acrosome damage. Oliveira et al. (Reference Oliveira, Arruda, Thomé, Maturana Filho, Oliveira, Guimarães, Nichi, Silva and Celeghini2014) showed that semen of Nellore sires with intact plasma and acrosome membranes and high mitochondrial potential resulted in increased pregnancy rates when compared with spermatozoa with membrane damage and diminished mitochondrial potential. The role of mitochondria in several intracellular processes related to sperm metabolism, cell signalling and sperm apoptosis has made the assessment of mitochondrial function a promising tool for the assessment of sperm fertilization capacity (Malama et al., Reference Malama, Zeron, Janett, Siuda, Roth and Bollwein2017; Leite et al., Reference Leite, Losano, Kawai, Rui, Nagai, Castiglioni, Siqueira, D’Avila Assumpção, Baruselli and Nichi2022).

With respect to sperm chromatin integrity, several studies have already shown that bull fertility and embryo development can be negatively affected when sperm DNA is damaged (Simões et al., Reference Simões, Feitosa, Siqueira, Nichi, Paula-Lopes, Marques, Peres, Barnabe, Visintin and Assumpção2013; Dogan et al., Reference Dogan, Vargovic, Oliveira, Belser, Kaya, Moura, Sutovsky, Parrish, Topper and Memili2015; Kumaresan et al., Reference Kumaresan, Johannisson, Al-Essawe and Morrell2017; Narud et al., Reference Narud, Klinkenberg, Khezri, Zeremichael, Stenseth, Nordborg, Haukaas, Morrell, Heringstad, Myromslien and Kommisrud2020). Nonetheless, in the present study, semen functional parameters were not different among sires. Even with no apparent impairment of sperm function, Wagyu bulls may have lower fertility as they have slower sperm cells and therefore may produce poorer quality embryos. This fact can decrease the pregnancy rate, which increases the cost of breeding. Given the considerable proportion of variation in bull fertility that yet remains not explained, it would be of interest to carry out a further study focusing on sperm molecular-based characterization and also explore other sperm features to identify possible cellular structures that may be related to the decline in bull fertility.

Reactive oxygen species (ROS) mediate essential intracellular signalling cascades needed for sperm physiological function, namely sperm flagellar hyperactivation, capacitation, and acrosome reaction, sperm oocyte interactions, signalling pathways involved in the fertilization, implantation and early embryo development (Agarwal and SenGupta, Reference Agarwal and SenGupta2020; Dutta et al., Reference Dutta, Henkel, Sengupta, Agarwal, Parekattil, Esteves and Agarwal2020; Alyethodi et al., Reference Alyethodi, Sirohi, Karthik, Tyagi, Perumal, Singh, Sharma and Kundu2021; Upadhyay et al., Reference Upadhyay, Ramesh, Dewry, Yadav and Ponraj2022). However, oxidative stress (imbalance of ROS not mitigated by the antioxidant mechanisms) may reduce sperm fertilizing ability due to toxicity (Ugur et al., Reference Ugur, Saber Abdelrahman, Evans, Gilmore, Hitit, Arifiantini, Purwantara, Kaya and Memili2019; Ribas-Maynou et al., Reference Ribas-Maynou, Yeste and Salas-Huetos2020; Saraf et al., Reference Saraf, Kumaresan, Sinha and Datta2021). Mitochondrial impairment and sperm DNA fragmentation are positively correlated with oxidative stress (Simões et al., Reference Simões, Feitosa, Siqueira, Nichi, Paula-Lopes, Marques, Peres, Barnabe, Visintin and Assumpção2013; Leite et al., Reference Leite, Losano, Kawai, Rui, Nagai, Castiglioni, Siqueira, D’Avila Assumpção, Baruselli and Nichi2022). It is known that frozen–thawed semen has an increased lipid peroxidation rate, once sperm cells are rich in polyunsaturated fatty acids and lack antioxidant enzyme defences (Amaral et al., Reference Amaral, Lourenço, Marques and Ramalho-Santos2013; Castiglioni et al., Reference Castiglioni, Siqueira, Bicudo, de Almeida, Hamilton, de Castro, Mendes, Nichi, Losano, Visitin and Assumpção2021; Pintus and Ros-Santaella, Reference Pintus and Ros-Santaella2021). Lipid peroxidation is considered a specific indicator of oxidative stress in sperm cells (Gallo et al., Reference Gallo, Esposito, Tosti and Boni2021). Indeed, there is damage caused by oxidative stress to the nature and amount of ROS involved and also on the duration of ROS exposure and extracellular factors, namely temperature, oxygen tension and the surrounding environment (Agarwal et al., Reference Agarwal, Makker and Sharma2008; Pintus and Ros-Santaella, Reference Pintus and Ros-Santaella2021).

In the present study, semen lipid peroxidation was not different among sires. Taken together with the results discussed above (sperm kinetics and sperm function analysis) it was possible to infer that the amount of ROS was not able (or sufficient) to trigger mitochondrial dysfunction, leading to altered respiratory chain activity, plasma membrane degradation, and thereby decreasing cell motility. The same was true for sperm DNA damage, as chromatin is the last cell structure to be affected by oxidative stress. It has been demonstrated that when sperm are exposed to low levels of oxidative stress, blastocyst formation is decreased, but not the cleavage rate. Conversely, when exposure to oxidative stress is severe, it is able to reduce cleavage and blastocyst rates, embryo quality and also compromise sperm DNA integrity (de Assis et al., Reference de Assis, Castro, Siqueira, Delgado, Hamilton, Goissis, Mendes, Nichi, Visintin and Assumpção2015; de Castro et al., Reference de Castro, de Assis, Siqueira, Hamilton, Mendes, Losano, Nichi, Visintin and Assumpção2016; Simões et al., Reference Simões, Feitosa, Siqueira, Nichi, Paula-Lopes, Marques, Peres, Barnabe, Visintin and Assumpção2013).

The relationship between testosterone and LH can be used to measure Leydig cell development (Teerds and Huhtaniemi, Reference Teerds and Huhtaniemi2015). Both are released in response to GnRH during puberty. Luteinizing hormone together with FSH is able to modulate testosterone synthesis in Leydig cells (Anand-Ivell et al., Reference Anand-Ivell, Byrne, Arnecke, Fair, Lonergan, Kenny and Ivell2019; Kowalczyk et al., Reference Kowalczyk, Gałęska, Czerniawska-Piątkowska, Szul and Hebda2021). Conversely, testosterone is an important hormone for spermatogenesis and is responsible for secondary sexual traits and libido (Kowalczyk et al., Reference Kowalczyk, Gałęska, Czerniawska-Piątkowska, Szul and Hebda2021). Also, testosterone is an important hormone in male fertility as its concentration in seminal plasma shows a positive correlation with sperm concentration, sperm motility, and other sperm traits (Souza et al., Reference Souza, Andrade, Celeghini, Negrão and Arruda2011).

In the present study, testosterone and LH serum concentration were not different among sires. Nonetheless, our results showed a higher testosterone serum concentration in Nellore bulls than found in a previous studies. Santos et al. (Reference Santos, Torres, Ruas, Guimarães and Silva Filho2004) observed an average of 4.04 ng/ml for the same bull breed. A similar result was shown in a study conducted by Amorim et al. (Reference Amorim, Kawamoto, Torres, Guimarães, Silva Filho, Oliveira, Carvalho and Fonseca2015) that found a serum testosterone concentration with an average of 5.41 ng/ml. In another study, Chacur et al. (Reference Chacur, Mizusaki, Filho, Oba and Ramos2013) evaluated seasonal effects on semen and testosterone concentration in Zebu (Nellore; Bos indicus) and taurine (Simental; Bos taurus) bulls. They showed that there was a difference between breeds when considering testosterone serum concentrations, demonstrating a higher adaptability of Nellore sires to the field conditions. Their results showed that Nellore had 2.34–4.3 ng/ml of serum testosterone and Simental had 5.84–9.01 ng/ml of serum testosterone. Interestingly, in the present study the mean testosterone serum concentration for Bos taurus (Angus bulls) was lower than for the data found by Chacur et al. (Reference Chacur, Mizusaki, Filho, Oba and Ramos2013). Despite differences between testosterone serum concentration in the present study and in previous literature, we showed that there was no difference for other sperm traits, except for sperm kinetics as discussed above.

One possible reason for the results present in this study is that the bulls were not grouped according to fertility or other traits, as the goal was to evaluate whether there were differences in the hormone and sperm characteristics of Wagyu bulls compared with the same characteristics of subspecies Bos indicus and Bos taurus sires. Moreover, the age of the bull could be an aspect that influenced the results as the mean ages of the Angus, Nellore, and Wagyu sires were 44.8, 39.0 and 12 months, respectively.

Bos indicus cattle are more resistant to higher temperature and humidity than Bos taurus. Indeed, as a consequence, its productivity and precocity are diminished. In general, Nellore bulls have slower testicular development and reach puberty later than Bos taurus (Nogueira, Reference Nogueira2004). According to Reis et al. (Reference Reis, Ramos, Camargos and Oba2016), Nellore puberty lasts from 18 to 26 months of age. In a study conducted by Brito et al. (Reference Brito, Silva, Unanian, Dode, Barbosa and Kastelic2004), age at puberty ranged from 17.6 to 22.4 months in Zebu (B. indicus) cattle. The seminal traits at this age were slightly poor, as mentioned above. Only after 26 months of age, with an increasing level of LH and testosterone, Nellore bulls reached sexual maturation. At this time, bulls exhibit an increased seminal quality (Reis et al., Reference Reis, Ramos, Camargos and Oba2016). Sexual maturity in B. taurus is achieved earlier than in B. indicus (Nogueira, Reference Nogueira2004; Brito, Reference Brito and Hopper2021). Fields et al. (Reference Fields, Hentges and Cornelisse1982) found an average age at puberty of 15.7 months for the Angus breed. In agreement with these results, Brito et al. (Reference Brito, Barth, Wilde and Kastelic2012) reported that Angus bulls reached puberty at 12.6 months of age and sexual maturity at 15.4 months old. Also, Tatman and co-workers (2022) observed that Angus bulls reached puberty at 12 months old. Considering Wagyu sires, to the best of our knowledge, there are scarce data available from Wagyu sire puberty. Tatman et al. (Reference Tatman, Chase, Wilson, Neuendorff, Lewis, Brown and Randel2022) found that Wagyu cattle were the youngest breed at puberty (10.7 months old). Casas et al. (Reference Casas, Lunstra, Cundiff and Ford2007) showed that the age at puberty was 10.06 months for Wagyu sires.

It is possible that we were not able to show significant differences between sires from different breeds considering sperm traits and sexual hormone levels because Nellore and Angus were older and probably more sexually mature than Wagyu sires. It is noteworthy that the presented data were based on a limited number of bulls. Perhaps, increasing the number of bulls and selecting animals with similar ages might allow additional significant relationships to be revealed. Once the present study was not able to find differences among Wagyu, Nellore, and Angus sires and some studies had pointed out that even Wagyu sires had a smaller scrotal circumference, had a higher libido and higher sperm production, therefore more studies are needed to determine what makes Wagyu different from other sires considering reproductive traits.

In conclusion, the results from the present study indicated that Wagyu sires had lower total motility when compared with Nellore and Angus bulls. This difference could be an effect of the high percentage of sperm with no motility observed in Wagyu semen. However, even failing the breeding soundness exams, because scrotal circumferences were too small, the Wagyu breed did not differ from those breeds when considering plasma and acrosome membranes integrity, mitochondrial potential, chromatin resistance, sperm lipid peroxidation or hormone (LH and testosterone) concentrations.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0967199423000278

Data availability

The authors confirm that the data supporting the findings of this study are available within the article and its supplementary materials.

Acknowledgements

We would like to thank Seleon Biotechnology (Itatinga, SP, Brazil) and Agropecuária Zanella (Paim Filho, RS, Brazil) for providing bull semen straws for our research.

Competing interests

The authors declare that they have no competing interests.

References

ABIEC. (2021). Perfil da Pecuária no Brasil: 2021 (Associação Brasileira das Indústrias Exportadoras de Carnes, Brasília, DF, 2021). https://agenciadenoticias.ibge.gov.br/agencia-sala-de-imprensa/2013-agencia-de-noticias/releases/31722-ppm-2020-rebanho-bovino-cresce-1–5-e-chega-a-218–2-milhoes-de-cabecas. Retrieved 3/8/2022Google Scholar
Agarwal, A. and SenGupta, P. (2020). Oxidative stress and its association with male infertility. doi: 10.1007/978-3-030-32300-4_6CrossRefGoogle Scholar
Agarwal, A., Makker, K. and Sharma, R. (2008). Clinical relevance of oxidative stress in male factor infertility: An update. American Journal of Reproductive Immunology, 59(1), 211. doi: 10.1111/j.1600-0897.2007.00559.x CrossRefGoogle ScholarPubMed
Alyethodi, R. R., Sirohi, A. S., Karthik, S., Tyagi, S., Perumal, P., Singh, U., Sharma, A. and Kundu, A. (2021). Role of seminal MDA, ROS, and antioxidants in cryopreservation and their kinetics under the influence of ejaculatory abstinence in bovine semen. Cryobiology, 98, 187193. doi: 10.1016/j.cryobiol.2020.11.002 CrossRefGoogle ScholarPubMed
Amann, R. P. and Waberski, D. (2014). Computer-assisted sperm analysis (CASA): Capabilities and potential developments. Theriogenology, 81(1), 517.e1. doi: 10.1016/j.theriogenology.2013.09.004 CrossRefGoogle ScholarPubMed
Amaral, A., Lourenço, B., Marques, M. and Ramalho-Santos, J. (2013). Mitochondria functionality and sperm quality. Reproduction, 146(5), R163R174. doi: 10.1530/REP-13-0178 CrossRefGoogle ScholarPubMed
Amorim, L. S., Kawamoto, T. S., Torres, C. A. A., Guimarães, J. D., Silva Filho, J. M., Oliveira, M. M. N. F., Carvalho, G. R. and Fonseca, J. F. (2015). Influência do Hormônio do Crescimento na concentração de testosterona plasmática e nas características seminais de touros jovens e adultos da raça Nelore. [Influence of growth hormone on plasma testosterone concentration and seminal characteristics of young and adult Nellore bulls.] Arquivo Brasileiro de Medicina Veterinária e Zootecnia, 67(1), 714. doi: 10.1590/1678-7189 CrossRefGoogle Scholar
Anand-Ivell, R., Byrne, C. J., Arnecke, J., Fair, S., Lonergan, P., Kenny, D. A. and Ivell, R. (2019). Prepubertal nutrition alters Leydig cell functional capacity and timing of puberty. PLOS ONE, 14(11), e0225465. doi: 10.1371/journal.pone.0225465 CrossRefGoogle ScholarPubMed
Bernecic, N. C., Donnellan, E., O’Callaghan, E., Kupisiewicz, K., O’Meara, C., Weldon, K., Lonergan, P., Kenny, D. A. and Fair, S. (2021). Comprehensive functional analysis reveals that acrosome integrity and viability are key variables distinguishing artificial insemination bulls of varying fertility. Journal of Dairy Science, 104(10), 1122611241. doi: 10.3168/jds.2021-20319 CrossRefGoogle ScholarPubMed
Bolt, D. J. and Rollins, R. (1983). Development and application of a radioimmunoassay for bovine follicle-stimulating hormone. Journal of Animal Science, 56(1), 146154. doi: 10.2527/jas1983.561146x CrossRefGoogle ScholarPubMed
Bolt, D. J., Scott, V. and Kiracofe, G. H. (1990). Plasma LH and FSH after estradiol, norgestomet and Gn-RH treatment in ovariectomized beef heifers. Animal Reproduction Science, 23(4), 263271. doi: 10.1016/0378-4320(90)90040-M CrossRefGoogle Scholar
Brazil, C., Swan, S. H., Tollner, C. R., Treece, C., Drobnis, E. Z., Wang, C., Redmon, J. B., Overstreet, J. W. and Study for Future Families Research Group. (2004). Quality control of laboratory methods for semen evaluation in a multicenter research study. Journal of Andrology, 25(4), 645656. doi: 10.1002/j.1939-4640.2004.tb02836.x CrossRefGoogle Scholar
Brito, L. F. C. (2021). Sexual development and puberty in bulls. In: Hopper, R.M. (ed.) Bovine Reproduction. John Wiley and Sons Inc., pp. 5878. doi: 10.1002/9781119602484.ch6 CrossRefGoogle Scholar
Brito, L. F. C., Silva, A. E., Unanian, M. M., Dode, M. A., Barbosa, R. T. and Kastelic, J. P. (2004). Sexual development in early- and late-maturing Bos indicus and Bos indicus × Bos taurus crossbred bulls in Brazil. Theriogenology, 62(7), 11981217. doi: 10.1016/j.theriogenology.2004.01.006 CrossRefGoogle ScholarPubMed
Brito, L. F. C., Barth, A. D., Wilde, R. E. and Kastelic, J. P. (2012). Effect of growth rate from 6 to 16 months of age on sexual development and reproductive function in beef bulls. Theriogenology, 77(7), 13981405. doi: 10.1016/j.theriogenology.2011.11.003 CrossRefGoogle ScholarPubMed
Casas, E., Lunstra, D. D., Cundiff, L. V. and Ford, J. J. (2007). Growth and pubertal development of F1 bulls from Hereford, Angus, Norwegian Red, Swedish Red and White, Friesian, and Wagyu sires. Journal of Animal Science, 85(11), 29042909. doi: 10.2527/jas.2007-0260 CrossRefGoogle ScholarPubMed
Castiglioni, V. C., Siqueira, A. F. P., Bicudo, L. C., de Almeida, T. G., Hamilton, T. R. D. S., de Castro, L. S., Mendes, C. M., Nichi, M., Losano, J. D. A., Visitin, J. A. and Assumpção, M. E. O. D. Á. (2021). Lipid peroxidation in bull semen influences sperm traits and oxidative potential of Percoll®-selected sperm. Zygote, 29(6), 476483. doi: 10.1017/S0967199421000228 CrossRefGoogle ScholarPubMed
Chacur, M. G. M., Mizusaki, K. T., Filho, L. R. A. G., Oba, E. & Ramos, A. A. (2013). Seasonal effects on semen and testosterone in Zebu and taurine bulls. Acta Scientiae Veterinariae, 41(1), 1110.Google Scholar
Connolly, S., Dona, A., Hamblin, D., D’Occhio, M. J. and González, L. A. (2020). Changes in the blood metabolome of Wagyu crossbred steers with time in the feedlot and relationships with marbling. Scientific Reports, 10(1), 18987. doi: 10.1038/s41598-020-76101-6 CrossRefGoogle ScholarPubMed
de Assis, P. M., Castro, L. S., Siqueira, A. F., Delgado, Jde C., Hamilton, T. R., Goissis, M. D., Mendes, C. M., Nichi, M., Visintin, J. A. and Assumpção, M. E. (2015). System for evaluation of oxidative stress on in-vitro-produced bovine embryos. Reproductive Biomedicine Online, 31(4), 577580. doi: 10.1016/j.rbmo.2015.06.014 CrossRefGoogle ScholarPubMed
de Castro, L. S., de Assis, P. M., Siqueira, A. F., Hamilton, T. R., Mendes, C. M., Losano, J. D., Nichi, M., Visintin, J. A. and Assumpção, M. E. (2016). Sperm oxidative stress is detrimental to embryo development: A dose-dependent study model and a new and more sensitive oxidative status evaluation. Oxidative Medicine and Cellular Longevity, 2016, 8213071. doi: 10.1155/2016/8213071 CrossRefGoogle Scholar
De Nadai Fernandes, E. A. N., Sarriés, G. A., Bacchi, M. A., Mazola, Y. T., Gonzaga, C. L. and Sarriés, S. R. V. (2020). Trace elements and machine learning for Brazilian beef traceability. Food Chemistry, 333, 127462. doi: 10.1016/j.foodchem.2020.127462 CrossRefGoogle ScholarPubMed
Dogan, S., Vargovic, P., Oliveira, R., Belser, L. E., Kaya, A., Moura, A., Sutovsky, P., Parrish, J., Topper, E. and Memili, E. (2015). Sperm protamine-status correlates to the fertility of breeding bulls. Biology of Reproduction, 92(4), 92. doi: 10.1095/biolreprod.114.124255 CrossRefGoogle Scholar
Dutta, S., Henkel, R., Sengupta, P. and Agarwal, A. (2020). Physiological role of ROS in sperm function. In: Parekattil, S., Esteves, S. & Agarwal, A. (eds) Male Infertility. Springer, Cham. doi: 10.1007/978-3-030-32300-4_27 Google ScholarPubMed
Facioli, F. L., De Marchi, F., Marques, M. G., Michelon, P. R. P., Zanella, E. L., Caires, K. C., Reeves, J. J. and Zanella, R. (2020). The outcome and economic viability of embryo production using IVF and SOV techniques in the Wagyu breed of cattle. Veterinary Sciences, 7(2), 58. doi: 10.3390/vetsci7020058 CrossRefGoogle ScholarPubMed
Fernandez-Novo, A., Santos-Lopez, S., Barrajon-Masa, C., Mozas, P., de Mercado, E., Caceres, E., Garrafa, A., Gonzalez-Martin, J. V., Perez-Villalobos, N., Oliet, A., Astiz, S. and Perez-Garnelo, S. S. (2021). Effect of extender, storage time and temperature on kinetic parameters (CASA) on bull semen samples. Biology, 10(8), 806. doi: 10.3390/biology10080806 CrossRefGoogle ScholarPubMed
Fields, M. J., Hentges, J. F. and Cornelisse, K. W. (1982). Aspects of the sexual development of Brahman versus Angus bulls in Florida. Theriogenology, 18(1), 1731. doi: 10.1016/0093-691x(82)90045-0 CrossRefGoogle ScholarPubMed
Gallo, A., Esposito, M. C., Tosti, E. and Boni, R. (2021). Sperm motility, oxidative status, and mitochondrial activity: Exploring correlation in different species. Antioxidants, 10(7), 1131. doi: 10.3390/antiox10071131 CrossRefGoogle ScholarPubMed
Goovaerts, I. G. F., Hoflack, G. G., Van Soom, A., Dewulf, J., Nichi, M., de Kruif, A. and Bols, P. E. (2006). Evaluation of epididymal semen quality using the Hamilton-Thorne analyser indicates variation between the two caudae epididymides of the same bull. Theriogenology, 66(2), 323330. doi: 10.1016/j.theriogenology.2005.11.018 CrossRefGoogle ScholarPubMed
Hoflack, G., Opsomer, G., Rijsselaere, T., Van Soom, A., Maes, D., de Kruif, A. and Duchateau, L. (2007). Comparison of computer-assisted sperm motility analysis parameters in semen from Belgian Blue and Holstein-Friesian bulls. Reproduction in Domestic Animals, 42(2), 153161. doi: 10.1111/j.1439-0531.2006.00745.x CrossRefGoogle ScholarPubMed
IBGE, censo agropecuário 2017. (2017). IBGE – Censo agro. https://biblioteca.ibge.gov.br/index.php/biblioteca-catalogo?view=detalhes&id=73096. Retrieved 11/5/2022.Google Scholar
Kathiravan, P., Kalatharan, J., Edwin, M. J. and Veerapandian, C. (2008). Computer automated motion analysis of crossbred bull spermatozoa and its relationship with in vitro fertility in zona-free hamster oocytes. Animal Reproduction Science, 104(1), 917. doi: 10.1016/j.anireprosci.2007.01.002 CrossRefGoogle ScholarPubMed
Kathiravan, P., Kalatharan, J., Karthikeya, G., Rengarajan, K. and Kadirvel, G. (2011). Objective sperm motion analysis to assess dairy bull fertility using computer-aided system – A review. Reproduction in Domestic Animals, 46(1), 165172. doi: 10.1111/j.1439-0531.2010.01603.x CrossRefGoogle ScholarPubMed
Kowalczyk, A., Gałęska, E., Czerniawska-Piątkowska, E., Szul, A. and Hebda, L. (2021). The impact of regular sperm donation on bull’s seminal plasma hormonal profile and phantom response. Scientific Reports, 11(1), 11116. doi: 10.1038/s41598-021-90630-8 CrossRefGoogle ScholarPubMed
Kumaresan, A., Johannisson, A., Al-Essawe, E. M. and Morrell, J. M. (2017). Sperm viability, reactive oxygen species, and DNA fragmentation index combined can discriminate between above- and below-average fertility bulls. Journal of Dairy Science, 100(7), 58245836. doi: 10.3168/jds.2016-12484 CrossRefGoogle ScholarPubMed
Kunz, G., Beil, D., Deiniger, H., Einspanier, A., Mall, G. and Leyendecker, G. (1997). The uterine peristaltic pump: Normal and impeded sperm transport within the female genital tract. Advances in Experimental Medicine and Biology, 424, 267277. doi: 10.1007/978-1-4615-5913-9_49 CrossRefGoogle ScholarPubMed
Ladeira, M. M., Schoonmaker, J. P., Swanson, K. C., Duckett, S. K., Gionbelli, M. P., Rodrigues, L. M. and Teixeira, P. D. (2018). Review: Nutrigenomics of marbling and fatty acid profile in ruminant meat. Animal: An International Journal of Animal Bioscience, 12(s2), s282s294. doi: 10.1017/S1751731118001933 CrossRefGoogle ScholarPubMed
Leite, R. F., de Agostini Losano, J. D., de Souza Ramos Angrimani, D., Sousa, R. G. B., de Miranda Alves, Á., Cavallin, M. D., Kawai, G. K. V., Cortada, C. N. M., Zuge, R. M. and Nichi, M. (2021). Reproductive parameters of Bos taurus and Bos indicus bulls during different seasons in tropical conditions: Focus on an alternative approach to testicular assessments using ultrasonography. Animal Reproduction Science, 225, 106668. doi: 10.1016/j.anireprosci.2020.106668 CrossRefGoogle Scholar
Leite, R. F., Losano, J. D. A., Kawai, G. K. V., Rui, B. R., Nagai, K. K., Castiglioni, V. C., Siqueira, A. F. P., D’Avila Assumpção, M. E. O., Baruselli, P. S. and Nichi, M. (2022). Sperm function and oxidative status: Effect on fertility in Bos taurus and Bos indicus bulls when semen is used for fixed-time artificial insemination. Animal Reproduction Science, 237, 106922. doi: 10.1016/j.anireprosci.2022.106922 CrossRefGoogle ScholarPubMed
Malama, E., Zeron, Y., Janett, F., Siuda, M., Roth, Z. and Bollwein, H. (2017). Use of computer-assisted sperm analysis and flow cytometry to detect seasonal variations of bovine semen quality. Theriogenology, 87, 7990. doi: 10.1016/j.theriogenology.2016.08.002 CrossRefGoogle ScholarPubMed
Miller, D. J. (2018). Review: The epic journey of sperm through the female reproductive tract. Animal: An International Journal of Animal Bioscience, 12(s1), s110s120. doi: 10.1017/S1751731118000526 CrossRefGoogle ScholarPubMed
Morrell, J. M., Valeanu, A. S., Lundeheim, N. and Johannisson, A. (2018). Sperm quality in frozen beef and dairy bull semen. Acta Veterinaria Scandinavica, 60(1), 41. doi: 10.1186/s13028-018-0396-2 CrossRefGoogle ScholarPubMed
Nagy, Á., Polichronopoulos, T., Gáspárdy, A., Solti, L. and Cseh, S. (2015). Correlation between bull fertility and sperm cell velocity parameters generated by computer-assisted semen analysis. Acta Veterinaria Hungarica, 63(3), 370381. doi: 10.1556/004.2015.035 CrossRefGoogle ScholarPubMed
Narud, B., Klinkenberg, G., Khezri, A., Zeremichael, T. T., Stenseth, E. B., Nordborg, A., Haukaas, T. H., Morrell, J. M., Heringstad, B., Myromslien, F. D. and Kommisrud, E. (2020). Differences in sperm functionality and intracellular metabolites in Norwegian Red bulls of contrasting fertility. Theriogenology, 157, 2432. doi: 10.1016/j.theriogenology.2020.07.005 CrossRefGoogle ScholarPubMed
Nichi, M., Bols, P. E., Züge, R. M., Barnabe, V. H., Goovaerts, I. G., Barnabe, R. C. and Cortada, C. N. (2006). Seasonal variation in semen quality in Bos indicus and Bos taurus bulls raised under tropical conditions. Theriogenology, 66(4), 822828. doi: 10.1016/j.theriogenology.2006.01.056 CrossRefGoogle ScholarPubMed
Nogueira, G. P. (2004). Puberty in South American Bos indicus (Zebu) cattle. Animal Reproduction Science, 82–83, 361372. doi: 10.1016/j.anireprosci.2004.04.007 CrossRefGoogle ScholarPubMed
Ohkawa, H., Ohishi, N. and Yagi, K. (1979). Assay for lipid peroxides in animal tissues by thiobarbituric acid reaction. Analytical Biochemistry, 95(2), 351358. doi: 10.1016/0003-2697(79)90738-3 CrossRefGoogle ScholarPubMed
Oliveira, L. Z., de Arruda, R. P., de Andrade, A. F., Celeghini, E. C., Reeb, P. D., Martins, J. P., dos Santos, R. M., Beletti, M. E., Peres, R. F., Monteiro, F. M. and Hossepian de Lima, V. F. (2013). Assessment of in vitro sperm characteristics and their importance in the prediction of conception rate in a bovine timed-AI program. Animal Reproduction Science, 137(3–4), 145155. doi: 10.1016/j.anireprosci.2013.01.010 CrossRefGoogle Scholar
Oliveira, B. M., Arruda, R. P., Thomé, H. E., Maturana Filho, M., Oliveira, G., Guimarães, C., Nichi, M., Silva, L. A. and Celeghini, E. C. (2014). Fertility and uterine hemodynamic in cows after artificial insemination with semen assessed by fluorescent probes. Theriogenology, 82(5), 767772. doi: 10.1016/j.theriogenology.2014.06.007 CrossRefGoogle ScholarPubMed
O’Meara, C., Henrotte, E., Kupisiewicz, K., Latour, C., Broekhuijse, M., Camus, A., Gavin-Plagne, L. and Sellem, E. (2022). The effect of adjusting settings within a computer-assisted sperm analysis (CASA) system on bovine sperm motility and morphology results. Animal Reproduction, 19(1), e20210077. doi: 10.1590/1984-3143-AR2021-0077 CrossRefGoogle ScholarPubMed
Parrish, J. J., Susko-Parrish, J., Winer, M. A. and First, N. L. (1988). Capacitation of bovine sperm by heparin. Biology of Reproduction, 38(5), 11711180. doi: 10.1095/biolreprod38.5.1171 CrossRefGoogle ScholarPubMed
Perumal, P., Srivastava, S. K., Ghosh, S. K. and Baruah, K. K. (2014). Computer-assisted sperm analysis of freezable and nonfreezable Mithun (Bos frontalis) semen. Journal of Animals, 2014, 16. doi: 10.1155/2014/675031 Google Scholar
Pintus, E. and Ros-Santaella, J. L. (2021). Impact of oxidative stress on male reproduction in domestic and wild animals. Antioxidants, 10(7), 1154. doi: 10.3390/antiox10071154 CrossRefGoogle ScholarPubMed
Radunz, A. E., Loerch, S. C., Lowe, G. D., Fluharty, F. L. and Zerby, H. N. (2009). Effect of Wagyu-versus Angus-sired calves on feedlot performance, carcass characteristics, and tenderness. Journal of Animal Science, 87(9), 29712976. doi: 10.2527/jas.2009-1914 CrossRefGoogle ScholarPubMed
Ratnawati, D. and Luthfi, M. (2020). Comparative study of sperms motility analysis with CASA by using leja and microscope slide. Jurnal Ilmu-Ilmu Peternakan, 30(2), 115122. doi: 10.21776/ub.jiip.2020.030.02.03 CrossRefGoogle Scholar
Reis, L. S. L. S., Ramos, A. A., Camargos, A. S. and Oba, E. (2016). Integrity of the plasma membrane, the acrossomal membrane, and the mitochondrial membrane potential of sperm in Nelore bulls from puberty to sexual maturity. Arquivo Brasileiro de Medicina Veterinária e Zootecnia, 68(3), 620628. doi: 10.1590/1678-4162-8748 CrossRefGoogle Scholar
Rezende-de-Souza, J. H., Cardello, F. A. B., de Paula, A. P. M., Ribeiro, F. A., Calkins, C. R. and Pflanzer, S. B. (2021). Profile of producers and production of dry-aged beef in Brazil. Foods, 10(10), 2447. doi: 10.3390/foods10102447 CrossRefGoogle ScholarPubMed
Ribas-Maynou, J., Yeste, M. and Salas-Huetos, A. (2020). The relationship between sperm oxidative stress alterations and IVF/ICSI outcomes: A systematic review from nonhuman mammals. Biology, 9(7), 178. doi: 10.3390/biology9070178 CrossRefGoogle ScholarPubMed
Robayo, I., Montenegro, V., Valdés, C. and Cox, J. F. (2008). CASA assessment of kinematic parameters of ram spermatozoa and their relationship to migration efficiency in ruminant cervical mucus. Reproduction in Domestic Animals, 43(4), 393399. doi: 10.1111/j.1439-0531.2007.00920.x CrossRefGoogle ScholarPubMed
Rodrigues, R. T. S., Chizzotti, M. L., Vital, C. E., Baracat-Pereira, M. C., Barros, E., Busato, K. C., Gomes, R. A., Ladeira, M. M. and Martins, T. D. (2017). Differences in beef quality between Angus (Bos taurus taurus) and Nellore (Bos taurus indicus) cattle through a proteomic and phosphoproteomic approach. PLOS ONE, 12(1), e0170294. doi: 10.1371/journal.pone.0170294 CrossRefGoogle ScholarPubMed
Rodrigues, N. N., Rossi, G. F., Vrisman, D. P., Taira, A. R., Souza, L. L., Zorzetto, M. F., Bastos, N. M., de Paz, C. C. P., de Lima, V. F. M. H., Monteiro, F. M. and Franco Oliveira, M. E. (2020). Ultrasonographic characteristics of the testes, epididymis and accessory sex glands and arterial spectral índices in peri- and post-pubertal Nelore and Caracu bulls. Animal Reproduction Science, 212, 106235. doi: 10.1016/j.anireprosci.2019.106235 CrossRefGoogle ScholarPubMed
Romanello, N., de Brito Lourenço Junior, J., Barioni Junior, W., Brandão, F. Z., Marcondes, C. R., Pezzopane, J. R. M., de Andrade Pantoja, M. H., Botta, D., Giro, A., Moura, A. B. B., do Nascimento Barreto, A. and Garcia, A. R. (2018). Thermoregulatory responses and reproductive traits in composite beef bulls raised in a tropical climate. International Journal of Biometeorology, 62(9), 15751586. doi: 10.1007/s00484-018-1557-8 CrossRefGoogle Scholar
Sansegundo, E., Tourmente, M. and Roldan, E. R. S. (2022). Energy metabolism and hyperactivation of spermatozoa from three mouse species under capacitating conditions. Cells, 11(2), 220. doi: 10.3390/cells11020220 CrossRefGoogle ScholarPubMed
Santos, M. D., Torres, C. A. A., Ruas, J. R. M., Guimarães, J. D. and Silva Filho, J. M. (2004). Reproductive potential of Nelore bulls submitted to different bull:cow proportion. Arquivo Brasileiro de Medicina Veterinária e Zootecnia, 56(4), 497503. doi: 10.1590/S0102-09352004000400011 CrossRefGoogle Scholar
Saraf, K. K., Kumaresan, A., Sinha, M. K. and Datta, T. K. (2021). Spermatozoal transcripts associated with oxidative stress and mitochondrial membrane potential differ between high- and low-fertile crossbred bulls. Andrologia, 53(5), e14029. doi: 10.1111/and.14029 CrossRefGoogle ScholarPubMed
Shi, Q. X. and Roldan, E. R. S. (1995). Bicarbonate/CO2 is not required for zona pellucida- or progesterone-induced acrosomal exocytosis of mouse spermatozoa but is essential for capacitation. Biology of Reproduction, 52(3), 540546. doi: 10.1095/biolreprod52.3.540 CrossRefGoogle ScholarPubMed
Silva, M. R., Pedrosa, V. B., Silva, J. C., Eler, J. P., Guimarães, J. D. and Albuquerque, L. G. (2011). Testicular traits as selection criteria for young Nellore bulls. Journal of Animal Science, 89(7), 20612067. doi: 10.2527/jas.2010-3525 CrossRefGoogle ScholarPubMed
Simões, R., Feitosa, W. B., Siqueira, A. F., Nichi, M., Paula-Lopes, F. F., Marques, M. G., Peres, M. A., Barnabe, V. H., Visintin, J. A. and Assumpção, M. E. (2013). Influence of bovine sperm DNA fragmentation and oxidative stress on early embryo in vitro development outcome. Reproduction, 146(5), 433441. doi: 10.1530/REP-13-0123 CrossRefGoogle ScholarPubMed
Singh, A. K., Kumar, A. and Bisla, A. (2021). Computer-assisted sperm analysis (CASA) in veterinary science: A review. Indian Journal of Animal Sciences, 91(6), 419429. doi: 10.56093/ijans.v91i6.115435 CrossRefGoogle Scholar
Siqueira, A. F. P., de Castro, L. S., de Assis, P. M., Bicudo, L. C., Mendes, C. M., Nichi, M., Visintin, J. A. and Assumpção, M. E. O. D. (2018). Sperm traits on in vitro production (IVP) of bovine embryos: Too much of anything is good for nothing. PLOS ONE, 13(7), e0200273. doi: 10.1371/journal.pone.0200273 CrossRefGoogle Scholar
Sosa, J. M., Senger, P. L. and Reeves, J. J. (2002). Evaluation of American Wagyu sires for scrotal circumference by age and body weight. Journal of Animal Science, 80(1), 1922. doi: 10.2527/2002.80119x CrossRefGoogle ScholarPubMed
Souza, L. W. O., Andrade, A. F. C., Celeghini, E. C. C., Negrão, J. A. and Arruda, R. Pd. (2011). Correlation between sperm characteristics and testosterone in bovine seminal plasma by direct radioimmunoassay. Revista Brasileira de Zootecnia, 40(12), 27212724. doi: 10.1590/S1516-35982011001200015 CrossRefGoogle Scholar
Tartaglione, C. M. and Ritta, M. N. (2004). Prognostic value of spermatological parameters as predictors of in vitro fertility of frozen–thawed bull semen. Theriogenology, 62(7), 12451252. doi: 10.1016/j.theriogenology.2004.01.012 CrossRefGoogle ScholarPubMed
Tatman, S. R., Chase, C. C., Wilson, T. W., Neuendorff, D. A., Lewis, A. W., Brown, C. G. & Randel, R. D. (2022). Comparison of reproductive development of recently introduced breeds to Angus and Brahman bulls. https://overton.tamu.edu/files/2022/03/article148.pdf. Retrieved 13/5/2022Google Scholar
Teerds, K. J. and Huhtaniemi, I. T. (2015). Morphological and functional maturation of Leydig cells: From rodent models to primates. Human Reproduction Update, 21(3), 310328. doi: 10.1093/humupd/dmv008 CrossRefGoogle ScholarPubMed
Teixeira, V. A., Coelho, S. G., Tomich, T. R., Pacheco Rodrigues, J. P., Camρos, M. M., Machado, F. S., Gualberto Barbosa da Silva, M. V., Monteiro, G. A. and Ribeiro Pereira, L. G. (2019). Reproductive characteristics of bulls from two breed compositions and their correlations with infrared thermography. Journal of Thermal Biology, 85, 102407. doi: 10.1016/j.jtherbio.2019.102407 CrossRefGoogle ScholarPubMed
Ugur, M. R., Saber Abdelrahman, A., Evans, H. C., Gilmore, A. A., Hitit, M., Arifiantini, R. I., Purwantara, B., Kaya, A. and Memili, E. (2019). Advances in cryopreservation of bull sperm. Frontiers in Veterinary Science, 6, 268. doi: 10.3389/fvets.2019.00268 CrossRefGoogle ScholarPubMed
Upadhyay, V. R., Ramesh, V., Dewry, R. K., Yadav, D. K. and Ponraj, P. (2022). Bimodal interplay of reactive oxygen and nitrogen species in physiology and pathophysiology of bovine sperm function. Theriogenology, 187, 8294. doi: 10.1016/j.theriogenology.2022.04.024 CrossRefGoogle ScholarPubMed
Utt, M. D. (2016). Prediction of bull fertility. Animal Reproduction Science, 169, 3744. doi: 10.1016/j.anireprosci.2015.12.011 CrossRefGoogle ScholarPubMed
Valverde, A., Barquero, V. and Soler, C. (2020). The application of computer-assisted semen analysis (CASA) technology to optimise semen evaluation. A review. Journal of Animal and Feed Sciences, 29(3), 189198. doi: 10.22358/jafs/127691/2020 CrossRefGoogle Scholar
Yánez-Ortiz, I., Catalán, J., Rodríguez-Gil, J. E., Miró, J. and Yeste, M. (2022). Advances in sperm cryopreservation in farm animals: Cattle, horse, pig and sheep. Animal Reproduction Science, 246, 106904. doi: 10.1016/j.anireprosci.2021.106904 CrossRefGoogle ScholarPubMed
Zu Ermgassen, E. K. H. J., Godar, J., Lathuillière, M. J., Löfgren, P., Gardner, T., Vasconcelos, A. and Meyfroidt, P. (2020). The origin, supply chain, and deforestation risk of Brazil’s beef exports. Proceedings of the National Academy of Sciences of the United States of America, 117(50), 3177031779. doi: 10.1073/pnas.2003270117 CrossRefGoogle ScholarPubMed
Figure 0

Figure 1. Mean ± standard error of the mean (SEM) of sperm kinetic analysis by computer-assisted sperm analysis (CASA). (a) Amplitude of lateral head displacement (ALH; µm). (b) Straightness (STR, VSL/VAP; %). (c) Linearity (LIN; %). (d) Total motility (MOT; %). (e) Medium movement (MEDIUM; %). (f) Static sperm (STATIC; %) in semen samples of Angus (n = 5), Nellore (n = 5) and Wagyu (n = 3) bull. Different superscript letters represent significant statistical differences (P < 0.05).

Figure 1

Table 1. Mean ± standard error of the mean (SEM) and probability (P) of sperm chromatin structure (SCSA), mitochondrial membrane potential (JC-1), acrosome and plasma membrane integrities (FITC–PI) and sperm lipid peroxidation status evaluated by induced thiobarbituric acid reactive substances (TBARS) assay among Angus (n = 5), Nellore (n = 5) and Wagyu (n = 3) bulls

Figure 2

Table 2. Mean ± standard error of the mean (SEM) and probability (P) of serum testosterone and luteinizing hormone (LH) concentrations among Angus (n = 5), Nellore (n = 5) and Wagyu (n = 3) bulls

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