Development of a programmable freezing technique on larval cryopreservation in Mytilus galloprovincialis

Journal Pre-proof Development of a programmable freezing technique on larval cryopreservation in Mytilus galloprovincialis Yibing Liu, Mark Gluis, Penny Miller-Ezzy, Jianguang Qin, Jiabo Han, Xin Zhan, Xiaoxu Li PII:

S0044-8486(19)31599-6

DOI:

https://doi.org/10.1016/j.aquaculture.2019.734554

Reference:

AQUA 734554

To appear in:

Aquaculture

Received Date: 27 June 2019 Revised Date:

28 September 2019

Accepted Date: 29 September 2019

Please cite this article as: Liu, Y., Gluis, M., Miller-Ezzy, P., Qin, J., Han, J., Zhan, X., Li, X., Development of a programmable freezing technique on larval cryopreservation in Mytilus galloprovincialis, Aquaculture (2019), doi: https://doi.org/10.1016/j.aquaculture.2019.734554. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier B.V.

Development of a programmable freezing technique on larval cryopreservation in Mytilus galloprovincialis Yibing Liu a, Mark Gluis b, Penny Miller-Ezzy b, Jianguang Qin c, Jiabo Han a, Xin Zhan d,*, Xiaoxu Li b,*

a

Dalian Key Laboratory of Conservation Biology for Endangered Marine mammals,

Liaoning Ocean and Fisheries Science Research Institute, Dalian, 116023, China b

South Australian Research and Development Institute - Aquatic Sciences Centre, Adelaide,

5024, Australia c

College of Science and Engineering, Flinders University, Adelaide, 5042, Australia

d

The Ocean College, Hainan University, Haikou, 570228, China

* Corresponding author: Xin Zhan Email: [email protected]

* Corresponding author: Xiaoxu Li Tel: ++ 61 8 8429 0504 Fax: ++ 61 8 8207 5481 Email: [email protected]

Highlights

This study developed a programmable freezing technique to cryopreserve larvae in Mytilus galloprovinvialis. The post-thaw survival rate has been improved significantly by the application of Ficoll and polyvinylpyrrolidone together. The technique can facilitate breeding programs and hatchery management in the mussel aquaculture industry.

Abstract This study investigated the factors important to the development of a programmable larval cryopreservation technique in Mytilus galloprovinvialis, including (1) larval developmental stages; (2) cryoprotectant agents (CPAs); (3) thawing temperatures; (4) sucrose concentrations to remove CPA after thawing and (5) straw volumes, using D-larval rate as the post-thaw survival indicator. The results showed that larvae at 25 h post-fertilization (PF) had the highest resistance to cryopreservation. A post-thaw D-larval rate higher than 80% was achieved when the larvae were cryopreserved with 10% ethylene glycol + 7.5% Ficoll + 0.2% polyvinylpyrrolidone, thawed at 28 °C and used 9% sucrose solution as the medium to remove CPA after thawing. No significant difference in post-thaw D-larval rates (P > 0.05) was found between larvae cryopreserved in 0.25 mL and 0.5 mL straws. The performance comparison experiment showed that although a significantly lower survival rate (P < 0.05) was found in cryopreserved larvae than that in fresh larvae at day 2 PF (D larvae), no significant difference (P > 0.05) was shown on relative mortality rate from day 8 PF (early umbonal larvae) to day 32 PF (spat) and on shell length at day 8 PF and day 32 PF between fresh and cryopreserved larvae. Therefore, the larval cryopreservation technique developed in this study would enhance the breeding program and all year-round hatchery production in this species.

Keywords: Mytilus galloprovinvialis, larval cryopreservation, Ficoll, polyvinylpyrrolidone

1

1. Introduction

2

Larval cryopreservation in aquaculture has been acknowledged as an effective and reliable

3

technique to preserve superior genetic resources, facilitate breeding design flexibility, provide

4

a reference family for selective breeding and supply larvae without seasonal limitation

5

(Zhang, 2004; Paredes et al., 2013; Labbé et al., 2018). However, larval cryopreservation in

6

marine bivalves is very difficult with few competent pediveliger larvae produced, < 3% in

7

oysters, clams and mussels (Chao et al., 1997; Lin et al., 1999; Usuki et al., 2005; Wang et al.,

8

2011; Paredes et al., 2012, 2013; Suneja et al., 2014; Labbé et al., 2018; Simon and Yang,

9

2018). The reasons causing this phenomenon are still unclear, may be due to that larvae in

10

marine bivalves are large in size and have large propositions of yolk, thus a low surface area

11

to volume ratio, leading to high sensitivity to cryopreservation (Ushijima et al., 1999; Seki et

12

al., 2007; Gosling, 2015).

13

Major steps in marine bivalve larval cryopreservation include (1) larval collection and

14

preparation; (2) cryoprotectant agent (CPA) stock solution preparations; (3) preparation of

15

CPA and larval suspension, and equilibration; (4) transfer CPA and larval suspension into

16

cryo-containers; (5) cooling by liquid nitrogen (LN) vapour; (6) storage in LN; (7) thawing

17

and CPA removal; and (8) post-thaw larval quality evaluation. In the development of a larval

18

cryopreservation technique, controlling the formation of intracellular ice is of importance.

19

One of the most effective strategies is to optimize CPAs or their combination to improve the

20

post-thaw survival rate (Massip et al., 2001; Jain and Paulson, 2006; Paredes et al., 2012;

21

Veleva et al., 2013; Liu and Li, 2015). Normally, CPA is divided into permeable and non-

22

permeable types depending on their ability to penetrate the cell membrane, a combination of

23

these two types is commonly used for the embryo cryopreservation in humans and livestock

24

species (Michelmann and Nayudu, 2006; Pereira and Marques, 2008; Youngs, 2011). In

25

Mytilus galloprovincialis larval cryopreservation, ethylene glycol has been shown as a

26

suitable permeable CPA, whereas a suitable non-permeable CPA is yet to be determined,

27

although sugars, such as polyvinylpyrrolidone and trehalose, have been evaluated (Wang et

28

al., 2011; Paredes et al., 2013). Recently, Ficoll has been found as an effective non-permeable

29

CPA for the oocyte cryopreservation in M. galloprovincialis (Liu and Li, 2015) which also

30

has shown beneficial effects in embryo cryopreservation of other species (Kuleshova et al.,

31

2001; Pereira and Marques, 2008). Nevertheless, Ficoll has not been evaluated on larval

32

cryopreservation in marine bivalves.

33

Methods to remove CPA after thawing are important for the success of embryo

34

cryopreservation, as inappropriate CPA removal could compromise embryo quality due to

35

osmotic pressure imbalance (Michelmann and Nayudu, 2006; Pereira and Marques, 2008). In

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humans and livestock species, these adverse osmotic effects have been mitigated by using

37

sucrose solution to remove the CPA after thawing (Michelmann and Nayudu, 2006; Pereira

38

and Marques, 2008; Youngs, 2011). However, this method has not been evaluated in marine

39

bivalves.

40

M. galloprovincialis is one of the most important bivalve species farmed in the world

41

(Pettersen et al., 2010; Paredes et al., 2013). In addition, their larvae have also been

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extensively utilized as a biological indicator in environmental monitoring programs (Jha et al.,

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2000; Geffard et al., 2002; Beiras et al., 2003). Therefore, development of a M.

44

galloprovincialis larval cryopreservation technique could be beneficial for providing

45

progenies without seasonal limitations not only for the aquaculture productions, but also for

46

environmental monitoring programs (Pettersen et al., 2010; Sánchez-Lazo and Martínez-Pita,

47

2012a, b). In our previous study in this species, we have found that the combination of Ficoll

48

and ethylene glycol as CPA and using 9% sucrose solution to remove CPA after thawing

49

were suitable for oocyte cryopreservation (Liu and Li, 2015). Therefore, in order to achieve

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the post-thaw larvae survival level that could potentially be used in M. galloprovincialis

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commercial production or other applications, such as, selective breeding, environment

52

monitoring, etc., the protocol developed from oocyte cryopreservation was investigated in

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this study with the purpose to develop a programmable freezing technique for larval

54

cryopreservation in M. galloprovincialis.

55

2. Materials and methods

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2.1. Larval collection

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Mature M. galloprovincialis were supplied by Kinkawooka Mussels in Port Lincoln, South

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Australia and transported in a refrigerated container overnight to South Australian Research

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and Development Institute (SARDI) - Aquatic Sciences Centre. Upon arrival, the animals

60

were washed with 1 µm filtered seawater (FSW) prior to spawning induction. Mussels were

61

spawned individually by thermal shock (increasing water temperature from 17 to 20 °C for

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30 min) and the gametes were collected as described by Liu and Li (2015). In each

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experiment, fresh eggs and sperm were collected from at least 10 and 5 individuals,

64

respectively. Fresh eggs were fertilized in a 2 L beaker at a sperm to egg ratio of 20:1. At 10

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min post-fertilization, the fertilized eggs were gently washed on a 35 µm screen and then

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cultured in 50 L tanks at a concentration of approximate 20 individuals mL-1 at 17 °C. When

67

the fertilized eggs were cultured for a predetermined time post-fertilization (PF), the larvae

68

were collected from the top of tanks on a 35 µm screen. The larvae were then transferred into

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10 mL tubes and stored on ice, which would minimize the potential temperature shock on

70

larvae when mixed with cold CPAs. The larvae density was counted and diluted to 4 x 105

71

individuals mL-1 for the subsequent experiments. The larvae stored on ice were used within

72

30 min in each experiment.

73

2.2. Chemicals and equipment

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All chemicals, ethylene glycol (EG), sucrose, Ficoll PM 70 (FIC) and polyvinylpyrrolidone

75

(PVP) were purchased from Sigma-Aldrich Pty Ltd (St. Louis, MO, USA). The

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cryoprotective stock solution was prepared in Milli-Q water at a concentration two times as

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high as that required in the experiments. Therefore, when the same volume of stock solution

78

and larvae suspension were mixed, the required final chemical concentration was produced.

79

The programmable controller applied in Liu and Li (2015) was used in this study. The

80

required temperatures in the thawing bath were produced by mixing ambient and boiled

81

seawater. The recovery bath (18 ºC) was produced by mixing ambient and cold seawater.

82

2.3. Experiments

83 84

2.3.1. Effects of different larval developmental stages on post-thaw D-larval rates

85

In this study, 10% EG + 7.5% FIC was selected as CPA because this combination has

86

produced the highest post-thaw D-larval rates in oocyte cryopreservation for this species (Liu

87

and Li, 2015). The larvae were collected at 10, 20, 25 and 30 h post-fertilization and were

88

mixed with CPA for 10 min on ice. The mixtures were then transferred into 0.25 mL straws

89

and maintained at 0 °C for 5 min in the programmable freezer. The straws were then cooled

90

at a rate of -1 °C/min from 0 to -10 °C and at -0.3 °C/min from -10 to -34 °C before being

91

plunged into LN. After at least 12 h storage in LN, the straws were thawed individually in a

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28°C water bath until the ice melted. They were then moved into an 18 °C seawater bath for

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recovery for approximately 5 min. The content in each straw was then expelled into a 4 mL

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tube and diluted for 10 min using 0.25 mL medium consisting of 9% sucrose. The CPA

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concentration was further diluted twice by adding a same volume of FSW as that in the tube

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at 10 min intervals. The larvae were then cultured in 500 mL containers until reaching D-

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larval stage (48 h post-fertilization). The D-larval rate was calculated as the percentage of

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larvae that develop into D-larvae. Controls were established and cultured in the same way as

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those cryopreserved. Each treatment was replicated three times.

100

2.3.2. Comparison of different CPAs on post-thaw D-larval rates

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The highest post-thaw D-larval rates were achieved when the larvae were cryopreserved at 25

102

h post-fertilization in the previous experiment. Therefore, this stage of larvae was used for

103

this and subsequent experiments. In this experiment, different CPAs, 10% EG, 10% EG + 7.5%

104

FIC, 10% EG + 0.2% PVP and 10% EG + 7.5% FIC + 0.2% PVP were evaluated for the

105

post-thaw D-larval rates. The other procedures were the same as Experiment 2.3.1

106 107 108 109

2.3.3. Effects of polyvinylpyrrolidone (PVP) concentrations on post-thaw Dlarval rates The CPA combination, 10% EG + 7.5% FIC + 0.2% PVP produced the highest post-thaw D-

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larval rates in the previous experiment. In this experiment, different PVP concentrations (0.05,

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0.1, 0.2 or 0.4%) were compared for post-thaw D-larval rates. The other procedures were the

112

same as Experiment 2.3.2.

113 114 115

2.3.4. Effects of thawing temperatures on post-thaw D-larval rates The highest post-thaw D-larval rates were achieved when the 0.2% PVP was added in 10%

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EG + 7.5% FIC in the previous experiment. Therefore, this CPA combination was used for

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this and subsequent experiments. In this experiment, thawing temperatures at 18, 28, 38, 48

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and 58 °C were evaluated on post-thaw D-larval rates. The other procedures were the same as

119

Experiment 2.3.3.

120 121 122 123

2.3.5. Effects of sucrose CPA dilution medium concentrations on post-thaw D-larval rates The highest post-thaw D-larval rates were achieved when a 28 °C thawing temperature was

124

used in the previous experiment. Thus, this temperature was used for this and subsequent

125

experiments. In this experiment, 6, 9, 12 and 15% sucrose solution were evaluated to dilute

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the CPA after thawing. The other procedures were the same as Experiment 2.3.4.

127 128 129

2.3.6. Effects of straw volumes on post-thaw D-larval rates Sucrose at concentration of 9% produced the highest post-thaw D-larval rates in the previous

130

experiment and this medium was used for this and subsequent experiments. In this

131

experiment, straw volume of 0.25 mL (Minitube, Germany) and 0.5 mL (IMV, France) was

132

evaluated on post-thaw D-larval rates. The other procedures were the same as Experiment

133

2.3.5.

134 135 136 137

2.3.7. Performance comparison between progenies produced with cryopreserved and fresh larvae The cryopreservation protocol (larvae: 25 h PF; CPA: 10% EG + 7.5% FIC + 0.2% PVP;

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post-thaw CPA removal medium: 9% sucrose; thawing temperature: 28 °C; straw volume: 0.5

139

mL) developed in this study was applied to compare the performance between progenies

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produced with fresh and cryopreserved larvae. After the assessment of D-larval rates, D

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larvae were transferred into 10 L tanks and stocked at a density of ～10 individuals mL-1 for

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cryopreserved larvae (3 tanks) and fresh larvae (3 tanks). Methods for larval culture and

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settlement were the same as those used by Wang et al. (2011) and Pettersen et al. (2010). The

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survival rate (%) was calculated in terms of dividing the number of alive on the sample

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collection date (PF) by the number of larvae initially stocked in the tank. The relative

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mortality rate (%) was calculated by dividing the difference in survival rate between adjacent

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sampling collection dates with the survival rate at the start of this period. At day 8 and day 32

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PF, 30 larvae from each tank were randomly selected to measure shell length.

149 150

2.4. Statistical analysis

151

The D-larval rate was normalized against the controls before data analysis. Data was

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normalized to the control mean percentage of larval abnormality using Abbot’s formula: P =

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(Pe-Pc)/(100-Pc) x 100, where Pc and Pe are control and experimental percentages of response,

154

respectively (Paredes et al., 2013). The data were presented as mean ± standard deviation (SD)

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and was arcsine transformed for statistical analyses using SPSS 22. One-way analysis of

156

variance (ANOVA) was applied to analyze the data on the effects of different larval stages,

157

different CPAs, different PVP concentrations, sucrose medium concentrations and thawing

158

temperatures on post-thaw D-larval rate. The Least-Significant Difference (LSD) comparison

159

test was used when significance was observed. A t-test was applied to compare the straw

160

volumes on D-larval rate after cryopreservation and a paired sample t-test was applied to

161

compare the performances (survival rate, relative mortality rate and spat size) between

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progenies produced with fresh and cryopreserved larvae. Differences were considered

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statistically significant at P < 0.05.

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3. Results

165

3.1. Effects of different larval developmental stages on post-thaw D-larval rate

166 167

The highest post-thaw D-larval rate of 62.6 ± 4.1% was achieved when the 25 h PF larvae

168

were cryopreserved, which was significantly higher than those collected at other periods (P <

169

0.05; Fig. 1).

170

3.2. Comparison of different CPAs on post-thaw D-larval rate

171 172

The addition of 7.5% FIC + 0.2% PVP in 10% EG significantly improved the post-thaw D-

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larval rate to 78.0 ±7.7% in comparison with 10% EG, 10% EG +7.5% FIC and 10% EG +

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0.2% PVP treatments (P < 0.05; Fig. 2). The addition of 7.5% FIC or 0.2% PVP in 10% EG

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did not affect the post-thaw D-larval rate in comparison with 10% EG alone (P > 0.05).

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3.3 Effects of polyvinylpyrrolidone (PVP) concentrations on post-thaw D-larval

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rate

178 179

The addition of 0.2% PVP in 10% EG + 7.5% FIC resulted in the highest post-thaw D-larval

180

rate of 84.0 ± 1.5% in comparison with 10% EG + 7.5% FIC and the addition of PVP at

181

other concentrations evaluated (P < 0.05; Fig. 3).

182 183 184

3.4. Effects of thawing temperatures on post-thaw D-larval rate The highest post-thaw D-larval rate of 80.5 ± 6.0% was produced when a 28 °C thawing

185

temperature was used (Fig. 4). This thawing temperature produced significantly higher post-

186

thaw D-larval rate than an 18 °C thawing temperature (P < 0.05), whereas no significant

187

difference was found in comparison with other thawing temperatures (P > 0.05).

188

3.5. Effects of sucrose CPA dilution medium concentrations on post-thaw D-

189

larval rate

190 191

Significantly higher post-thaw D-larval rate was produced when the 9% sucrose was used as

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a medium to dilute the CPA after thawing in comparison with either the lower or higher

193

sucrose concentrations evaluated (P < 0.05; Fig. 5).

194 195 196

3.6. Effects of straw volumes on post-thaw D-larval rate No significant difference was found when the larvae were cryopreserved in 0.25 and 0.5 mL

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straws (P > 0.05), resulting in 78.4 ± 6.3% and 78.0 ± 5.8% post-thaw D-larval rates,

198

respectively.

199 200

3.7. Performance comparison between progenies produced with cryopreserved and fresh larvae

201 202

Table 1 demonstrated that the survival rate of fresh larvae was significantly higher than that

203

of cryopreserved larvae at all the periods PF evaluated (P < 0.05). However, after day 8 PF,

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there was no significant difference in relative mortality rate between fresh and cryopreserved

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larvae. Moreover, no significant difference (P > 0.05) in shell length was found between

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fresh and cryopreserved progenies at day 8 PF (fresh larvae: 146.7 ± 5.8 µm; cryopreserved

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larvae: 143.9 ± 2.5 µm, n = 90) and day 32 PF (fresh larvae: 380.0 ± 8.7 µm; cryopreserved

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larvae 371.7 ± 9.1 µm, n = 90).

209 210

4. Discussion

211

This study has developed a programmable larval cryopreservation technique for M.

212

galloprovincialis. The post-thaw larval survival rate was improved to >80% when the 25 h

213

post-fertilization larvae were cryopreserved with 10% EG + 7.5% FIC + 0.2% PVP, thawed

214

at 28 °C and using 9% sucrose solution as medium to remove CPA after thawing.

215

It has been generally acknowledged that larval age is of importance for cryosurvival, as

216

larvae at different developmental stages have various ability to be cryopresered (Gwo 1995;

217

Nascimento et al., 2005; Paredes et al., 2012, 2013). In this study, M. galloprovincialis larvae

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collected at 25 h post-fertilization had the highest resistance to cryopreservation, with 62%

219

post-thaw D-larval rates achieved. This developmental stage was later than Paredes et al.

220

(2013) study (20 h) on the same species with about 50% post-thaw D-larval rates produced.

221

This difference may be related to early larvae having more lipid, which is stored as an energy

222

reserve and used for larval development (Bayne et al., 1978; Gosling, 2015). An embryo with

223

high lipid content would be more sensitive to cryopreservation and this phenomenon has been

224

shown in livestock species, such as pigs (Nagashima et al., 1995; Dobrinsky 2002), cattle

225

(Massip 2001; Pryor et al., 2011) and sheep (Massip 2001).

226

Ethylene glycol has been shown as a suitable permeable CPA in larval cryopreservation in M.

227

galloprovincialis and Perna canaliculus (Paredes et al., 2012, 2013). For the non-permeable

228

CPAs, on the other hand, although some sugars such as trehalose and PVP have been

229

investigated in mussels and oysters, no spat has been produced in the published results

230

(Paredes et al., 2012, 2013). In our previous study, the non-permeable CPA, FIC,

231

demonstrated the ability to significantly improve the post-thaw oocyte quality in M.

232

galloprovincialis (Liu and Li, 2015). Although the PVP was not used for the larval

233

cryopreservation in this species (Paredes et al., 2013), it has been applied in mice and cattle

234

cryopreservation (Leibo and Oda, 1993; Saha et al., 1996; Titterington and Robinson, 1996;

235

Kim et al., 2008). Furthermore, some studies have shown that a combination of different non-

236

permeable CPAs could be more effective for improving the cryosurvival rate of larvae (Saha

237

et al., 1996; Titterington and Robinson, 1996). In this study, 10% EG + 7.5% FIC and 10%

238

EG + 0.2% PVP had the similar cryoprotective ability as 10% EG used alone (Fig. 2). This is

239

in agreement with the study by Paredes et al. (2013) on the same species where 10% EG with

240

or without trehalose produced a similar post-thaw D-larval rate. However, in the present

241

study, when the 7.5% FIC was applied with 0.2% PVP together, the post-thaw D-larval rate

242

was significantly improved (Fig 2, 3). This result indicates that the combined effects of FIC

243

and PVP could play an important role in M. galloprovincialis larval cryopreservation.

244

Reasons for this improvement are not clear, although it might be because the intercellular ice

245

formation is limited by the application of suitable non-permeable CPAs as suggested by Gao

246

and Critser (2000) in their review on cryoinjury mechanisms. In addition, further study would

247

be needed to determine if any correlation between the improvement in post-thaw survival rate

248

achieved in this study and the toxicity of CPAs used. Result in this study agrees with the

249

study reported by Saha et al. (1996) that the hatching rate was improved significantly when

250

cattle embryos were cryopreserved in EG (40%) plus two sugars (11.3% trehalose + 20%

251

PVP) in comparison with EG used alone or in combination with either sugars.

252

Thawing temperature is a critical factor affecting the success of larval cryopreservation. High

253

thawing temperature could inhibit recrystallization of the internal ice, while a low

254

temperature might prevent osmotic pressure on the larvae as extracellular medium melts fast.

255

The reduced pressure could result in a rapid shift of free water into the larvae if the

256

intracellular CPA cannot diffuse out quickly, leading to extreme larval swelling, and possible

257

rupture (Jain and Paulson, 2006). Therefore, controlling thawing temperature is necessary,

258

although studies in this area have been lacking in marine bivalves. In this study, 28 °C was

259

the optimal thawing temperature for M. galloprovincialis larval cryopreservation. This

260

temperature has also been applied for the oocyte and larval cryopreservation in the same

261

species (Paredes et al., 2013; Liu and Li, 2015), Crassostrea gigas (Lin et al., 1999; Paredes

262

et al., 2013; Suneja et al., 2014) and P. canaliculus (Paredes et al., 2012). This temperature is

263

higher than that applied in Pinctada fucata martensii (25 °C; Choi and Chang, 2003).

264

Besides thawing temperature, application of proper medium to remove CPA from the larvae

265

after thawing could also improve the success of cryopreservation (Woods et al., 2004; Jain

266

and Paulson, 2006). Medium containing sucrose has been widely used to remove CPA in

267

embryo cryopreservation in cattle (Mahmoudzadeh et al., 1993; Youngs, 2011), dogs

268

(Guaitolini et al., 2012), sheep (Youngs, 2011), mice (Fathi et al., 2012) and pigs (Castillo-

269

Martín et al., 2013). In the larvae cryopreservation of marine mollusc species, seawater and

270

bovine serum albumin are commonly used to remove CPA in oysters (Lin et al., 1999; Choi

271

and Chang, 2003; Paredes et al., 2013; Suneja et al., 2014) and mussels (Wang et al., 2011;

272

Paredes et al., 2012, 2013), although low or no spat productions were reported in these

273

studies. In the current study, 9% sucrose solution achieved the highest post-thaw D-larval

274

rates (Fig. 5) which has also been used on the oocyte cryopreservation in the same species

275

(Liu and Li, 2015).

276

Different straw volumes have different surface to volume ratio which is important for

277

cryosurvival. Higher surface to volume ratio could enable a uniform cooling rate and proper

278

heat exchange properties which would be advantageous for maintaining cell quality (Zhu et

279

al., 2014). In this study, 0.25 mL and 0.5 mL straws produced similar post-thaw D-larval

280

rates. This is in agreement with a study on P. canaliculus larvae cryopreservation where no

281

significant difference on post-thaw D-larval rate was found when larvae were cryopreserved

282

in 0.25 mL and 0.5 mL straws (Paredes et al., 2012).

283

After cryopreservation, the developmental capacity of larvae is reduced, resulting in a

284

significantly lower survival rate compared to fresh larvae (Table 1). This phenomenon has

285

been observed in other studies, as the mechanism of cell cleavage might be compromised

286

during cryopreservation (Wang et al., 2011; Paredes et al., 2012). Nevertheless, in the present

287

study, the relative mortality rates after day 8 PF remained the same between fresh and

288

cryopreserved larvae (Table 1). Moreover, the shell length of larvae at day 8 and spat at day

289

32 PF was similar (P > 0.05) between the fresh and cryopreserved larvae. Therefore, the

290

results of this study indicate that cryopreservation affects the larvae at an early developmental

291

stage in M. galloprovincialis. Similar phenomenon has also been observed in other studies on

292

the same species (Wang et al., 2011; Paredes et al., 2012, 2013; Liu and Li, 2015).

293

In conclusion, the larval cryopreservation technique developed in this study has significantly

294

improved the post-thaw D-larval rate to >80% in M. galloprovincialis with cryodamage being

295

expressed only at early development stages. Therefore, this technique could be applied to

296

guarantee a reliable year round supply of progenies for hatchery production and

297

environmental monitoring programs, and enhance the management efficiency of breeding

298

programs in the M. galloprovincialis aquaculture industry.

299

300

Acknowledgments

301

This research was funded by the Talent Project of Revitalizing Liaoning (Project No.

302

XLYC1807087), Department of Ocean and Fisheries of Liaoning (Project No. 201829),

303

China Scholarship Council and South Australian Research and Development Institute

304

(SARDI). We thank Mr Andy Dyer of Kinkawooka Mussels for the provision of mussel

305

broodstock. We also thank master student Zhongling Lin of Dalian Ocean University for

306

technical assistance.

307 308

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424

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425 426 427 428

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431

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432

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434

Table Legend

435

Table 1. Comparison of survival rates and relative mortality rate between fresh and

436

cryopreserved larvae during periods post-fertilization, n = 3. Different letter indicates

437

significant difference (P < 0.05).

438

Table 1.

Survival rate (%)

Relative mortality rate (%)

Days post fertilization

fresh larvae

cryopreserved larvae

day 2 (D larvae)

91.7 ± 3.0 A

71.6 ± 0.9 B

day 8

72.0 ± 3.9 A′

44.5 ± 1.3 B′

21.3 ± 6.4 b

37.8 ± 1.9 a

day 14

59.3 ± 5.1 A″

37.3 ± 5.4 B″

17.2 ± 11.8 a′

16.3 ± 9.5 a′

fresh larvae

cryopreserved larvae

day 20

48.7 ± 3.5 A‴

30.3 ± 1.2 B‴

17.8 ± 6.1 a″

17.9 ± 9.5 a″

day 26 (eyed larvae)

46.7 ± 2.7 A″″

28.5 ± 2.3 B″″

3.8 ± 6.7 a‴

6.1 ± 5.3 a‴

day 32 (spat)

37.5 ± 1.5 A″‴

21.3 ± 0.6 B″‴

19.7 ± 1.5 a″″

25.0 ± 4.4 a″″

439

Figure Legends

440

Fig. 1. Post-thaw D-larval rates (%) when larvae were cryopreserved at different

441

developmental stages, n = 3. Different letter indicates significant difference (P < 0.05). All

442

the data has been normalized to the controls.

443

Fig. 2. Post-thaw D-larval rates (%) when larvae were cryopreserved in different CPA

444

combination(s), n = 3. Different letter indicates significant difference (P < 0.05). All the data

445

has been normalized to the controls.

446

Fig. 3. Post-thaw D-larval rates (%) when larvae were cryopreserved in 10% EG + 7.5% FIC

447

with addition of different concentrations of PVP, n = 3. Different letter indicates significant

448

difference (P < 0.05). All the data has been normalized to the controls.

449

Fig. 4. Post-thaw D-larval rates (%) of larvae thawed at various thawing temperatures after

450

cryopreservation, n = 3. Different letter indicates significant difference (P < 0.05). All the

451

data has been normalized to the controls.

452

Fig. 5. Post-thaw D-larval rates (%) of larvae diluted with different concentrations of sucrose

453

after thawing, n = 3. Different letter indicates significant difference (P < 0.05). All the data

454

has been normalized to the controls.

100.0

D-larval rate (%)

80.0 A 60.0 B 40.0

C

C

20.0

0.0 10 h

455 456

Fig.1.

20 h 25 h Periods post-fertilization

30 h

457 100.0 A

D-larval rate (%)

80.0 B

60.0 B

B

40.0

20.0

0.0 10% EG

458 459 460

Fig.2.

10% EG + 7.5% FIC

10% EG + 0.2% PVP 10% EG + 7.5% FIC + 0.2% PVP

100.0 A B

D-larval rate (%)

80.0

B

B 60.0

C

40.0 20.0 0.0 10% EG + 7.5% 10% EG + 7.5% 10% EG + 7.5% 10% EG + 7.5% 10% EG + 7.5% FIC FIC + 0.05% PVP FIC + 0.1% PVP FIC + 0.2% PVP FIC + 0.4% PVP Cryoprotectant agents

461 462

Fig.3.

100 A

D-larval rate (%)

80

AB

B

AB

AB

60 40 20 0 18°C

463 464

Fig.4.

28°C

38°C 48°C Thawing temperatures

58°C

100.0 A D-larval rate (%)

80.0 B

B

B

60.0 40.0 20.0 0.0 6% sucrose

465 466

Fig.5.

9% sucrose 12% sucrose Sucrose concentrations

15% sucrose

Highlights

This study developed a programmable freezing technique to cryopreserve larvae in Mytilus galloprovinvialis. The post-thaw survival rate has been improved significantly by the application of Ficoll and polyvinylpyrrolidone together. The technique can facilitate breeding programs and hatchery management in the mussel aquaculture industry.