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Advances in Animal and Veterinary Sciences

AAVS_MH20160128160145_Ponraj et al

 

 

Research Article

 

Casa Parameters of Mithun Semen Treated with Melatonin

 

Perumal Ponraj1*, Kishore Kumar Baruah 2, Kobu Khate1, Neeraj Srivastava3, Jeetendra Singh Rajoriya4, Sukkum Chang1

1Animal Reproduction Lab, ICAR-National Research Centre on Mithun, Jharnapani, Nagaland – 797106 India; 2ICAR-National Research Centre on Pig, Rani, Guwahati, Assam, India; 3ICAR- Central Institute for Research on Cattle, Meerut, UP, India; 4Department of AR GO, College of Veterinary Science & Animal Husbandry, Rewa, MP, India.

 

Abstract | A study was conducted to measure the effect of melatonin (MT) on motility and velocity parameters of mithun semen by Computer Assisted Sperm Analyser (CASA) in different seasons. Total numbers of 80 ejaculates (20 ejaculates in each season) were collected twice a week from mithun bulls and were split into five equal aliquots, diluted with the Tris Egg Yolk Citrate (TEYC) extender. Group 1: semen without additives (control), group 2 to group 6: semen was diluted with 1, 2, 3, 4 and 5 mM of melatonin, respectively. CASA parameter such as Forward Progressive Motility (FPM), Total Motility (TM), Curvilinear Velocity (VCL), Straight Line Velocity (VSL), Average Path Velocity (VAP), Linearity (LIN), Straightness (STR), Amplitude of Lateral Head displacement (ALH) and Beat / Cross Frequency (BCF) were measured after 12 hrs of incubation at 5oC. Blood samples were collected in different seasons to estimate the melatonin. The results revealed that these parameters were varied significantly (p<0.05) among the different experimental groups and among the seasons. Further, MT at 3 mM has significant improvement than other treatment groups stored in in- vitro at different seasons. Additionally, spring season has highest value followed by winter and autumn season, whereas lower values were in summer season. Melatonin concentration was higher in winter season and lowest was in summer season. The result of the study indicated that the melatonin protects CASA parameters, varied in different seasons. It was concluded that ejaculates from spring and winter season has significantly higher CASA parameters in mithun.

 

Keywords | melatonin, mithun, computer assisted sperm analysis, seasons

 

Editor | M. Saminathan (M.V.Sc), Division of Pathology, ICAR-Indian Veterinary Research Institute (ICAR-IVRI), Izatnagar, Bareilly, Uttar Pradesh, India

Special Issue | 2, 2016 “Emerging Challenges and Opportunities in Veterinary Research for Improvement of Animal Health”.

Received | January 28, 2016; Revised | March 25, 2016; Accepted | March 28, 2016; Published | April 06, 2016

*Correspondence | Perumal Ponraj, Scientist, Animal Reproduction Lab, ICAR-National Research Centre on Mithun, Jharnapani, Nagaland–797106, India; Email: perumalponraj@gmail.com

Citation | Ponraj P, Baruah KK, Khate K, Srivastava N, Rajoriya JS, Chang S (2016). Casa parameters of mithun semen treated with melatonin. Adv. Anim. Vet. Sci. 4(2s): 5-12.

DOI | http://dx.doi.org/10.14737/journal.aavs/2016/4.2s.5.12

ISSN (Online) | 2307-8316; ISSN (Print) | 2309-3331

Copyright © 2016 Ponraj et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

 

INTRODUCTION

 

Seasonality is one of the most important factors that influence the reproduction and production potential (Mathevon et al., 1998). Semen quality parameters are significantly influenced by the seasons. Thermal tolerance capacity of indigenous cattle is better than exotic cattle indicated good quality semen and lower sperm abnormalities (Rajoriya et al., 2013). The testes are extremely sensitive to high ambient temperature, resulting in degenerative changes characterized by reduction in testicular size, change in its structure, consistency and functions (McEntee, 1990). It is poorly understood that to what extent the seasonal effect on the reproduction performance in mithun species. Liquid storage of semen at refrigerator temperature is used to decrease metabolism and to maintain quality and viability of the sperm for an extended period of time. But the sperm quality is decreased in the extended period of storage. Antioxidants are naturally present in mammalian semen to counteract the reactive oxygen species (ROS) to protect the sperm (Akhter et al., 2011). However, the concentration of these antioxidants is decreased during the process of dilution and preservation (Kumar et al., 2011). Hence synthetic or natural antioxidants should be included in the semen extender at the time of dilution (Perumal et al., 2013). Thus enhance the quality in chilled liquid semen preservation (Perumal et al., 2013; Perumal et al., 2015).

 

Melatonin is an indole derivative of endogenous compound secreted rhythmically from the pineal gland in the brain and influences in the circadian clock and seasonal reproduction in mammals (Reiter, 1991). Melatonin and its metabolites act as the powerful antioxidant and antiapoptotic agent (Reiter et al., 1998). It has been reported that melatonin has potency twice against peroxyl radicals as that of vitamin E in action (Pieri et al., 1994) and also it is more effective in scavenging of the hydroxyl radicals than mannitol and reduced glutathione (Hardeland et al., 1993). Melatonin is associated with mitochondrial membrane potential (Acuna-Castroviejo et al., 2011), ATP production (Chen et al., 1994), interaction with calmodulin (Tash et al., 1983), stimulates cellular influx of Ca2+ into sperm cells (Delgadillo et al., 1994) and cyclic AMP (cAMP) stimulator (Yung et al., 1995), through which the melatonin stimulate the sperm to get higher motility and velocity.

 

Antioxidant effects of melatonin on seminal parameters were studied in various species (Ram: Casao et al., 2010; Ashrafi et al., 2011, Boar: Martin-Hildago et al., 2011, Bull: Ashrafi et al., 2013, Mithun: Perumal et al., 2013; Perumal et al., 2015) in refrigerated or in the unfrozen storage. Literatures study revealed no report on effect of season and melatonin on mobility and velocity parameters in mithun species. Therefore, the present study was designed to measure the motility and velocity parameters in semen extended with melatonin at different concentration in liquid refrigerated preservation at different seasons in mithun.

 

MATERIAL AND METHODS

 

Experimental Animals

Ten apparently healthy mithun bulls of approximately 4 to 6 year of age with good body condition (score 5-6) were selected from the herd of mithun farm, ICAR-NRC on Mithun, Jharnapani, Nagaland India, which is located between 25°54ʹ30ʹʹ North Latitude and 93°44ʹ15ʹʹ East Longitude and at an altitude range of 250-300 feet Mean Sea Level. Month wise THI was calculated and the year has been divided in to four seasons as per the THI (winter: 54.41, spring: 63.50, summer: 76.05 and autumn: 74.00). These animals were maintained under uniform feeding, housing and managemental conditions. The feeding practices were followed as per the farm schedule. Semen was collected from the animals through trans-rectal massage method.

 

Semen Collection and Processing

The collection seasons were split into four viz. spring (February to April), summer (May to July), autumn (August to October) and winter (November to January). Total numbers of 80 ejaculates (20 ejaculates from each season) were collected from the mithun bulls twice a week. Immediately after collection, the samples were kept in a water bath at 37oC and evaluated basic seminal parameters. After the preliminary evaluations, samples were subjected to the initial dilution with pre-warmed (37oC) TEYC. The partially diluted samples were then brought to the laboratory in an insulated flask containing warm water (37oC) for further processing. Each ejaculate was split into six equal aliquots and diluted with the TEYC extender with melatonin. Group 1: semen without additives (control), group 2 to group 6: semen with 1, 2, 3, 4 and 5 mM of melatonin, respectively. Diluted semen samples were kept in glass tubes and cooled from 37 to 5oC, at a rate of 0.2 – 0.3oC/min in a cold cabinet and maintained at 5oC during liquid storage for up to a 12 hrs period of the experiment. The motility and velocity parameters were estimated by image CASA analyzer as per standard procedure for different seasons.

 

Computer Assisted Sperm Analysis

The sperm motility and velocity parameters were evaluated by Hamilton Thorne Sperm Analyser, version IVOS 11 (HTM-IVOS, Version 10.8, Hamilton Thorne Research, Beverly, MA, USA). This CASA system consists of a phase-contrast microscope, camera, mini-thermal heating stage, image digitizer and computer saving and analyzing the data. The software settings were arranged as follows. Chamber type: Leja 4, temperature of analysis (ºC): 37.0, fields acquired: 10, frame rate (Hz): 60, number of frames: 30, minimum static contrast: 35, minimum cell size (pixels): 5, STR (%): 70, VAP cut – off (µm/s): 30, Prog.min VAP (µm/s): 50, VSL cut-off (µm/s): 15, cell intensity: 80 and magnification: 1.89.

 

After semen collection, the sperm concentration was first estimated using a phase-contrast microscope (Nikon, Eclipse 80i; 400× magnification). 25 μL of semen was diluted into 50-100 μL of Tris (formulated for bull semen) and 5 μL of this diluted semen was loaded into a pre-warmed dual chamber disposable Leja slide and was allowed to settle on the minitherm heating stage (37°C) before the analysis. The following parameters such as percentage of TM, FPM, velocity of rapid, medium, slow and static, VAP (μm/sec), VSL (μm/sec), VCL (μm/sec), ALH (μm), BCF (Hz), STR (%) and LIN (%) were measured. A minimum of 200 spermatozoa from at least two different

 

Table 1: Mean (±S.E.) total motility, Forward Progressive Motility and velocity of rapid and static for mithun semen following storage at 5oC for different seasons

CASA Parameters

Additives

Seasons

Winter

Spring

Summer

Autumn

Total Motility

Control

71.70 ± 1.88bB

75.10 ± 1.97bcB

62.30 ± 2.44cA

65.45 ± 2.40cA

MT 1 mM

73.75 ± 1.84bcB

75.30 ± 2.12bcB

67.80 ± 2.21dA

68.40 ± 2.19cdA

MT 2 mM

74.85 ± 1.94cB

77.40 ± 2.10caB

67.00 ± 2.21dA

70.40 ± 1.89dA

MT 3 mM

77.85 ± 1.80dBC

79.70 ± 1.96dC

70.60 ± 1.68dA

75.65 ± 1.63eB

MT 4 mM

72.25 ± 1.76bcC

72.35 ± 1.54bC

57.35 ± 1.70bA

60.90 ± 1.69bB

MT 5 mM

65.05 ± 1.45aC

68.80 ± 1.50aD

50.80 ± 1.29aA

56.80 ± 1.65aB

Forward Progressive Motility

Control

28.90 ± 1.97abB

33.85 ± 2.38bcC

19.80 ± 2.05aA

29.35 ± 1.86cB

MT 1 mM

30.40 ± 2.17abBC

32.10 ± 2.46abC

24.00 ± 2.30bcA

26.65 ± 2.54bcAB

MT 2 mM

32.60 ± 2.13bcB

38.80 ± 2.40cC

26.30 ± 2.28cA

28.75 ± 2.32cAB

MT 3 mM

35.50 ± 2.34cB

38.25 ± 2.42cB

27.65 ± 2.10cA

34.50 ± 2.24dB

MT 4 mM

32.65 ± 2.22bcB

34.15 ± 2.48bcB

20.35 ± 2.04abA

23.65 ± 2.27abA

MT 5 mM

26.20 ± 2.50aB

27.85 ± 2.12aB

17.95 ± 1.87aA

21.50 ± 2.44aA

Rapid velocity

Control

60.15 ± 3.06abBC

67.70 ± 2.91bC

49.20 ± 3.09bcA

54.80 ± 3.38bcAB

MT 1 mM

65.05 ± 2.95bcC

68.40 ± 2.50bC

48.10 ± 2.49bcA

57.50 ± 2.86bcB

MT 2 mM

70.90 ± 2.53cdB

72.35 ± 2.61bcB

53.05 ± 3.84cdA

58.70 ± 2.91cA

MT 3 mM

77.15 ± 1.73dBC

78.25 ± 2.06cC

61.25 ± 2.76dA

73.75 ± 2.23dB

MT 4 mM

63.85 ± 2.59abB

65.80 ± 2.72bB

43.40 ± 2.66abA

49.70 ± 3.10bA

MT 5 mM

56.90 ± 3.10aB

56.70 ± 2.97aB

39.10 ± 2.73aA

38.90 ± 2.98aA

Static velocity

Control

13.45 ± 2.58abA

14.70 ± 2.03abAB

20.25 ± 2.27abC

19.40 ± 2.99bBC

MT 1 mM

14.80 ± 2.56b

13.50 ± 2.43ab

17.55 ± 2.94ab

16.45 ± 2.77ab

MT 2 mM

12.20 ± 1.65ab

12.90 ± 2.09a

14.35 ± 2.69a

15.25 ± 2.73ab

MT 3 mM

9.10 ± 1.81aA

10.15 ± 2.07aA

15.25 ± 2.59aB

10.65 ± 2.26aA

MT 4 mM

16.30 ± 2.33bA

18.60 ± 2.74bAB

22.70 ± 2.34bB

21.05 ± 3.07bAB

MT 5 mM

16.25 ± 2.62bA

18.65 ± 2.91bA

31.25 ± 3.16cB

19.90 ± 3.16bA

 

Within columns means with different letters (a, b, c, d) differ significantly (P < 0.05)

Within rows means with different letters (A, B, C, D) differ significantly (P < 0.05)

 

drops of each sample were analyzed from each specimen. The number of objects was incorrectly identified as spermatozoa were manually removed and final analysis was done for each sample.

 

Blood Collection, Plasma Separation and Estimation of the Hormone

Seven ml of blood samples were collected randomly immediately after semen collection from the external jugular vein in tubes with heparin anticoagulant for different seasons. Plasma was separated from blood by centrifugation at 3500 g at 4°C for 20 min. The plasma was stored in frozen state at -80°C until further analysis. Melatonin was estimated with radio immuno assay kit (Anand Brothers, New Delhi, India).

 

Statistical Analysis

The results were analysed statistically and expressed as the mean ± S.E.M. Means were analyzed by one way analysis of variance (ANOVA), followed by the Tukey’s post hoc test to determine significant differences between the different seasons with additives or without additive and between the treatment and control groups on different seasons on the sperm mobility and velocity parameters using the SPSS/PC computer program (version 15.0; SPSS, Chicago, IL). Differences with values of p<0.05 were considered to be statistically significant after arcsine transformation of percentage data

.

RESULTS AND DISCUSSION

 

In the present study, the CASA parameters such as TM (Table 1), FPM (Table 1), velocity of rapid and static (Table 1), VAP (Table 2), VSL (Table 2), VCL (Table 2), ALH (Table 3), BCF (Table 3), STR (Table 3) and LIN (Table 3) were significantly (p<0.05) higher in melatonin 3 mM treated group as compared to control and other MT treated groups. Moreover, MT 3 mM treated and other experimental groups have significantly (p<0.05) higher percentage in the spring followed by winter and least was

 

Table 2: Mean (±S.E.) average path velocity, Straight Line Velocity and Curve Linear Velocity of mithun sperm following storage at 5oC for different seasons

CASA parameters

Additives

Seasons

Winter

Spring

Summer

Autumn

Average Path Velocity

Control

112.42 ± 5.35ab

120.34 ± 5.17ab

103.54 ± 4.65ab

109.11 ± 5.13ab

MT 1 mM

111.02 ± 4.60abB

125.86 ± 4.18abB

91.82 ± 3.98abA

110.44 ± 4.87abB

MT 2 mM

130.51 ± 5.43bcB

134.90 ± 4.51bB

105.87 ± 5.78abA

111.07 ± 5.09abA

MT 3 mM

138.02 ± 4.29cB

139.53 ± 4.82bB

111.13 ± 5.13bA

132.61 ± 4.30bAB

MT 4 mM

122.97 ± 5.32abcB

126.25 ± 5.42abB

86.25 ± 3.25aA

105.86 ± 5.09aAB

MT 5 mM

101.94 ± 4.91aAB

112.67 ± 4.87aB

92.07 ± 5.27abA

96.96 ± 4.37aAB

Straight Line Velocity

Control

78.75 ±4.26abB

87.00 ± 4.47abB

58.99 ± 2.98abA

74.48 ± 3.68abB

MT 1 mM

86.97 ± 4.28bcAB

90.69 ± 4.70abB

72.78 ± 4.82bA

77.63 ± 4.53abAB

MT 2 mM

90.49 ± 3.83bcBC

94.57 ± 5.11bC

70.67 ± 4.23abA

77.26 ± 4.29abAB

MT 3 mM

95.87 ± 4.25cB

95.10 ± 3.88bB

74.50 ± 4.21bA

88.38 ± 4.76bAB

MT 4 mM

77.24 ± 4.23abB

85.49 ± 3.88abC

55.85 ± 2.80aA

71.61 ± 4.58abAB

MT 5 mM

69.61 ± 3.69aAB

80.13 ± 4.27aB

66.72 ± 4.61abA

68.66 ± 4.05aAB

Curve Linear Velocity

Control

207.59 ± 7.19abAB

225.46 ± 7.09aB

179.87 ± 5.19abA

202.97 ± 6.94aAB

MT 1 mM

209.86 ± 6.55abAB

236.75 ± 5.82abB

195.76 ± 5.83abA

217.14 ± 6.02abAB

MT 2 mM

242.67 ± 7.34bcAB

253.26 ± 6.05bB

202.70 ± 8.15bA

249.92 ± 5.25bcB

MT 3 mM

253.84 ± 5.08c

254.63 ± 5.23b

214.33 ± 6.85b

255.62 ± 6.16c

MT 4 mM

200.34 ± 6.82aAB

228.70 ± 7.16aB

173.83 ± 4.85abA

220.94 ± 6.74abcB

MT 5 mM

182.26 ± 6.29aAB

202.92 ± 6.22aB

160.00 ± 7.83aA

197.84 ± 6.42aAB

 

Within columns means with different letters (a, b, c, d) differ significantly (P < 0.05)

Within rows means with different letters (A, B, C, D) differ significantly (P < 0.05)

 

in summer season. The CASA parameters were increased to MT 3 mM treated group then decreased to MT 4 and 5 mM. Additionally, melatonin at 1, 2, 4 and 5 mM were inferior to MT 3 mM treatments for these motility parameters and there was a significant (p< 0.05) difference between melatonin at 1, 2, 4, 5 mM and 3 mM for these response at different seasons. Moreover, MT 4 and 5 mM treated groups have significantly (p< 0.05) lower value than untreated control group. The concentration of melatonin in serum on different seasons revealed a significant (p<0.05) difference among the seasons and was significantly (p< 0.05) highest in winter followed by spring, autumn and lowest was in summer season.

 

The results of inclusion of melatonin has improved the motility and velocity parameters of mithun sperm in different seasons and was higher in spring followed by winter, autumn and lowest was in summer season. The literature study revealed that there was no report on effect of inclusion of MT on CASA parameters in mithun semen in different seasons and to the best of our knowledge; this is the first report on the effect of MT on these CASA profiles in different seasons in mithun semen. However, there was some reports available on effect of MT on semen quality parameters preserved at liquid state upto 30 hrs of incubation (Perumal et al., 2013) and at different seasons (Perumal et al., 2015) and also some studies were conducted on CASA parameters in mithun semen preservation (Perumal et al., 2014). In the previous studies, it has been reported that MT has improved the semen quality parameters, antioxidant profiles and reduced leakage of intra cellular enzymatic profiles in liquid semen preservation in mithun (Perumal et al., 2013; Perumal et al., 2015). Moreover, it reduced the production malondialdehyde and cholesterol efflux as preserved in liquid state (Perumal et al., 2013; Perumal et al., 2015). However, many authors reported that MT has beneficial effects on preservation of mammalian sperm and improves the velocity and mobility parameters of spermatozoa (Ashrafi et al., 2011; Ashrafi et al., 2013) and also on semen quality parameters (Casao et al., 2010; Ashrafi et al., 2011; Ashrafi et al., 2013; Perumal et al., 2013; Perumal et al., 2015).

 

Melatonin has improved the velocity and mobility parameters of mithun semen in dose depended manner in different seasons (Casao et al., 2010; Perumal et al., 2013; Perumal et al., 2015) as 3 mM MT is being the most effective and optimum concentration and spring and winter are more suitable seasons. Thus, melatonin in the sperm extender induced higher viability rates, a greater percentage of total motile and progressive motile spermatozoa, a larger number of sperm with higher medium or rapid velocity and elevated intracellular ATP concentrations as reported in the previous studies (Perumal et al., 2013; Perumal et al.,

 

Table 3: Mean (±S.E.) amplitude of lateral head displacement, Beat Cross Frequency, Straightness and Linearity of mithun sperm following storage at 5oC for different seasons

CASA parameters

Additives

Seasons

Winter

Spring

Summer

Autumn

Amplitude Of Lateral Head Displacement

Control

9.34 ± 1.11abAB

10.30 ± 1.09aB

8.70 ± 1.13aA

9.50 ± 1.20abAB

MT 1 mM

10.11 ± 2.07b

10.16 ± 1.03a

9.27 ± 1.37ab

9.44 ± 1.32ab

MT 2 mM

10.10 ± 0.86b

10.35 ± 1.88a

9.10 ± 1.15ab

9.79 ± 1.16b

MT 3 mM

10.18 ± 0.99b

14.09 ± 4.37b

9.71 ± 1.18b

9.90 ± 1.21b

MT 4 mM

9.37 ± 1.06ab

9.56 ± 1.76a

8.76 ± 0.99ab

9.35 ± 1.08ab

MT 5 mM

8.90 ± 1.30a

9.41 ± 1.78a

8.88 ± 1.10ab

8.62 ± 1.18a

Beat Cross Frequency

Control

25.37 ± 2.24

26.19 ± 2.37ab

22.55 ± 1.86

23.60 ± 3.15

MT 1 mM

24.89 ± 2.33

27.01 ± 3.15ab

23.51 ± 2.26

24.25 ± 1.89

MT 2 mM

24.80 ± 2.17AB

27.30 ± 2.02abB

23.76 ± 1.78A

24.57 ± 2.22AB

MT 3 mM

25.88 ± 1.64A

29.96 ± 2.32bB

24.07 ± 2.27A

24.70 ± 2.19A

MT 4 mM

24.50 ± 2.35AB

25.22 ± 2.02abB

22.86 ± 2.09AB

22.01 ± 1.76A

MT 5 mM

23.96 ± 1.76AB

24.56 ± 2.00aB

22.91 ± 2.30AB

21.50 ± 2.09A

Straightness

Control

66.35 ± 2.21abAB

66.75 ± 2.08abB

63.70 ± 2.14abA

64.45 ± 1.64AB

MT 1 mM

65.45 ± 1.74abA

69.80 ± 2.61abB

64.35 ± 1.98abA

64.95 ± 1.85A

MT 2 mM

66.65 ± 2.68abAB

70.15 ± 1.86bB

64.75 ± 2.06abA

65.80 ± 2.94AB

MT 3 mM

68.55 ± 2.70bAB

70.40 ± 2.57bB

67.30 ± 1.88bAB

66.00 ± 2.70A

MT 4 mM

66.30 ± 2.07ab

66.55 ± 2.68ab

65.45 ± 2.14ab

65.45 ± 2.24

MT 5 mM

63.15 ± 2.73a

66.10 ± 2.24a

63.20 ± 2.03a

64.00 ± 1.82

Linearity

Control

38.05 ± 2.16abAB

38.60 ± 2.23B

35.40 ± 1.89abA

35.65 ± 2.01A

MT 1 mM

38.75 ± 2.38abAB

40.65 ± 3.08B

34.65 ± 1.77abA

36.95 ± 2.46AB

MT 2 mM

37.80 ± 2.12abAB

41.15 ± 2.92B

36.45 ± 2.25abA

37.20 ± 2.71AB

MT 3 mM

40.55 ± 2.80bAB

41.50 ± 2.13B

37.85 ± 1.96bA

37.65 ± 2.27A

MT 4 mM

36.85 ± 1.73aAB

39.65 ± 3.38B

34.25 ± 2.28abA

36.55 ± 2.76AB

MT 5 mM

36.70 ± 2.16AB

38.30 ± 3.14B

33.80 ± 1.96aA

34.45 ± 1.68AB

 

Within columns means with different letters (a, b, c, d) differ significantly (P < 0.05)

Within rows means with different letters (A, B, C, D) differ significantly (P < 0.05)

 

2015). Moreover, melatonin protects the mitochondria and plasma membrane from the free radical and leads to higher mitochondrial membrane potential, cell viability, membrane fluidity, acrosomal integrity and reduced lipid peroxidation (Garcia et al., 1997). Seasons are also influenced on the LPO production and antioxidant concentration as higher antioxidant was reported in winter as compared to summer season and higher LPO was in summer than in winter season in semen of Tharparkar bull (Rajoriya et al., 2013).

 

Melatonin has improved the mobility and velocity parameters in the present study as because of its interaction with calmodulin (Benitez-King and Anton-Tay, 1993) which in turn influences cytoskeletal elements of sperm and impacted higher sperm motility and velocity. Thus melatonin protects the sperm from stress and damage during the processing of dilution, extension and preservation. It has been speculated that melatonin is being produced in the ovary served as the activating and chemoattractant agent that aids hyperactivation of sperm leads to increased mobility and velocity to reach the fertilization site (Fujinoki, 2008). In the present study also indicated the optimum dosage of MT was 3 mM that may be the optimum concentration of MT secreted by the female reproductive tract and/or ovary for higher mobility and velocity for reach to site of fertilization and fertilization and to confirm this, need to estimate the concentration of melatonin in the liquids secreted in female reproductive tract and organ. Similarly in the present study, MT 3 mM as an optimum dose to preserve the semen in liquid state.

 

Enhanced effect of MT on sperm motility and velocity parameters may be due to it increases ATPase levels (Chen et al., 1994), inturn increases ATP production which is the main source energy used by the sperm flagellum to initiate and activate forward progressive motility and different velocity parameters (Burger et al., 1991). Melatonin also stimulates cellular influx of Ca2+ into sperm cells enhancing their motility (Delgadillo et al., 1994). Calcium and its channels control the transition from symmetric to asymmetric flagella waveforms (Si, 1997) and calmodulin acts as an intracellular regulator of Ca2+ function and have been identified both in the head and flagellar parts of spermatozoa (Tash and Means, 1983) and are believed to be a major signal transducer in Ca2+ regulating motility. Calmodulin antagonist or lack of melatonin caused a reduction in VCL and ALH and it is related with mitochondrial membrane potential and mobility & velocity of the spermatozoa (Ahmad et al., 1996). These results suggested that melatonin has enhanced the regulatory role of Ca2+/calmodulin pathway in sperm motility and velocity parameters including VCL and ALH in liquid storage of mithun semen. Moreover, melatonin has improved the mobility and velocity through act on the cyclic AMP (cAMP) stimulator (Yung et al., 1995) and cAMP stimulates sperm motility via its direct action on the axoneme of the tail (Lindamann, 1978) or indirectly through acting on the cell membrane as secondary messenger (Garbers and Kopf, 1980). Thus the melatonin treated sperm has higher motility and velocity parameters in the present study.

 

Melatonin increased the sperm mobility and velocity attributes in the present study as because melatonin decreased significantly sperm abnormalities and acid phosphatase level during preservation in the extender (Mamdouh et al., 1996) as it can pass into the cell membrane and protects mitochondria and DNA from free radical and ROS damaging effect through its potent antioxidant and anti-aging effects on the cells (Poeggeler et al., 1993). Moreover, melatonin lowers the levels of acid phosphatase enzyme as it is considered as an indicator of cellular death or damage or poor integrity of membrane (Moss and Henderson, 1993). Thus melatonin has improved sperm progressive motility as it has decreasing effect on the phosphatase enzyme release and leakage from sperm cells during preservation (Mamdouh et al., 1996).

 

The different effects of the different levels of melatonin might be explained according to the report of Ashrafi et al. (2011), Perumal et al. (2013) and Perumal et al. (2015) showed that the excessive amount of antioxidants caused high fluidity of plasma membrane above the desired point, making sperm more prone to acrosomal damages. Moreover, the concentration of antioxidants added to extender should be considered since high dosage of antioxidants may be harmful to spermatozoa due to the change in physiological condition of semen extender. In mithun, survival, mobility and velocity of spermatozoa were increased as the dosage of antioxidant added to extender increased. However, the antioxidant dosage higher than required amount was toxic to spermatozoa (Perumal et al., 2013; Perumal et al., 2015). The over expression of melatonin may reflect a defect in the development or maturation of spermatozoa, as well as sperm cellular damage, resulting in decreased sperm fertilization potential (Ashrafi et al., 2013). Similarly, in the previous study, increasing dosage of melatonin, more than 3 mM affected the seminal as well as biochemical parameters in mithun semen preserved with TEYC extender (Perumal et al., 2013; Perumal et al., 2015). At the same time, less dosage rate also affected the sperm parameters. But as per the dosage, these velocity and mobility parameters were increased upto 3 mM then decreased to 5 mM.

 

The improvement of semen quality due to addition of exogenous melatonin recorded in the present study was previously reported (Casao et al., 2010; Ashrafi et al., 2011; Ashrafi et al., 2013; Perumal et al., 2013; Perumal et al., 2015). Moreover, the addition of exogenous melatonin was significantly improving the percentages of DNA morphology, sperm viability and intact plasma membrane (swelling tails) especially at the optimum (3 mM) level of melatonin was reported in the previous study (Perumal et al., 2013; Perumal et al., 2015). The highest percentages of intact plasma and acrosomal membranes which were found in the previous experiments due to 3 mM melatonin may be the reason for better motility and velocity in the present study (Perumal et al., 2013; Perumal et al., 2015; Ashrafi et al., 2013).

 

In the present study, the concentration of MT decreased in serum of summer season because the thermo stress and long photoperiod leads decreased production of melatonin and also affects the normal function of testes and accessory sex glands as similar in cryptorchid testes (Ahotupa et al., 1992) and summer stressed animals. In the previous study, leakage of intracellular enzyme was lowered in semen preserved at 3 mM of melatonin at liquid storage period indicated that it stabilised the membrane integrity of acrosome, plasma, mitochondria and flagella of the sperm (Perumal et al., 2013; Perumal et al., 2015) and was lower in spring and autumn season than summer season as the summer hot and winter cold stress affect the function of accessory glands, seminal vesicle and epididymis that leads to poor plasma membrane and acrosomal membrane stability leads to more leakage of intra cellular enzymes in summer season. Moreover, functions of these glands depend upon the androgen; summer stress cause secretion of androgen is affected. Thus the sperm from summer season has poor quality, stability, motility and velocity in the present study.

 

In the present study, velocity and mobility profiles were higher in spring and winter seasons, the seasons have short day light. This indicates that during this short day season, there was more secretion of melatonin in mithun and protected the seminal, biochemical and antioxidant parameters along with stimulation of hypothalamus to secrete more GnRH followed by high semen production. Moreover, there may be high variation in melatonin secretion and concentration throughout the year in mithun blood and seminal plasma that could partly explain the differences in sperm quality and fertility observed between the different seasons (Ashrafi et al., 2013) in mithun species. The concentration of melatonin in different seasons also indicated that higher value was observed in winter and spring seasons than in summer season and thus may be the reason, the semen from spring and winter season has higher velocity and motility. Similarly, in mithun cows, short day may induce secretion of melatonin; stimulate GnRH secretion followed by expression of heat, breeding, conception and calving. But in the present study, we didn’t measure the concentration of melatonin and other reproductive hormones of female animals in different seasons. However, in the previous study, highest calving rate in mithun was from November to February (winter season) followed by August to October (autumn season) indicated most of the breeding was taken during the winter and spring seasons (November to April) than in summer season (May to July) (Perumal et al., 2015).

 

In this study, improvements were observed in sperm velocity and motility in dose dependent manner in different seasons by means of the antioxidant property of melatonin. Thus it may protect the spermatozoa during preservation and enhancing the fertility in this species at 3 mM. Further, semen production and effect of melatonin on these CASA parameters were differed among the seasons and were higher in spring season followed by winter and autumn season whereas lowest in the summer season. From this it was concluded that collection and preservation of semen should be conducted during spring and winter season for artificial insemination but more suitable breeding season for mithun from winter to spring season (November to April). Future, ultra-low temperature sperm preservation/cryoprotective studies and correlated study with endocrinological profiles at different seasons are warranted to confirm the present findings.

 

ACKNOWLEDGEMENT

 

This research work was supported by a grant from the Department of Biotechnology, Government of India, New Delhi for the project entitled “Evaluation of melatonin as fertility marker in Mithun (Bos frontalis) bulls: Effect on circadian rhythm and seasonal variation in semen quality parameters”.

 

Conflict of interest

 

None of the authors have any conflict of interest to declare.

 

Authors Contribution

 

Perumal Ponraj: Plan of work, execution, analysis of data and manuscript preparation; Kishore Kumar Baruah: Plan of work, technical assistance, analysis of data and manuscript preparation; Kobu Khate: Technical assistance and analysis of data; Neeraj Srivastava: Manuscript preparation and correction; Jeetendra Singh Rajoriya: Lab work assistance and Sukkum Chang: Lab work assistance.

 

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    Advances in Animal and Veterinary Sciences

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