Non-Lethal Heat Shock of the Asian Green Mussel, Perna viridis, Promotes Hsp70 Synthesis, Induces Thermotolerance and Protects Against Vibrio Infection

Nor Afiqah Aleng; Yeong Yik Sung; Thomas H. MacRae; Mohd Effendy Abd Wahid

doi:10.1371/journal.pone.0135603

Abstract

Mild heat stress promotes thermotolerance and protection against several different stresses in aquatic animals, consequences correlated with the accumulation of heat shock protein 70 (Hsp70). The purpose of this study was to determine if non-lethal heat shock (NLHS) of the Asian green mussel, Perna viridis, an aquatic species of commercial value, promoted the production of Hsp70 and enhanced its resistance to stresses. Initially, the LT₅₀ and LHT for P. viridis were determined to be 42°C and 44°C, respectively, with no heat shock induced death of mussels at 40°C or less. Immunoprobing of western blots revealed augmentation of constitutive (PvHsp70-1) and inducible (PvHsp70-2) Hsp70 in tissue from adductor muscle, foot, gill and mantel of P. viridis exposed to 38°C for 30 min followed by 6 h recovery, NLHS conditions for this organism. Characterization by liquid chromatography-tandem mass spectrometry (LC-MS/MS) revealed that PvHsp70-1 and PvHsp70-2 respectively corresponded most closely to Hsp70 from P. viridis and Mytilus galloprovincialis. Priming of adult mussels with NLHS promoted thermotolerance and increased resistance to V. alginolyticus. The induction of Hsp70 in parallel with enhanced thermotolerance and improved protection against V. alginolyticus, suggests Hsp70 functions in P. viridis as a molecular chaperone and as a stimulator of the immune system.

Citation: Aleng NA, Sung YY, MacRae TH, Abd Wahid ME (2015) Non-Lethal Heat Shock of the Asian Green Mussel, Perna viridis, Promotes Hsp70 Synthesis, Induces Thermotolerance and Protects Against Vibrio Infection. PLoS ONE 10(8): e0135603. https://doi.org/10.1371/journal.pone.0135603

Editor: Eric A. Shelden, Washington State University, UNITED STATES

Received: January 25, 2015; Accepted: July 24, 2015; Published: August 19, 2015

Copyright: © 2015 Aleng et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited

Data Availability: All relevant data are within the paper and its Supporting Information files.

Funding: Funded by E-Science Fund No: 04-01-12-SS0109 from the Ministry of Science, Technology and Innovation (MOSTI), Malaysia to MEAW (www.mosti.gov.my), ERGS No. 55090 from the Ministry of Education, Malaysia(www.moe.gov.my) to YYS, and Natural Sciences and Engineering Research Council Discovery Grant to THM.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Aquatic organisms experience environmental stresses including temperature fluctuation, salinity shift, oxygen deprivation and pollution [1–3] as well as disease-causing biotic stressors such as bacteria, virus, fungi and parasites [4]. Stress disrupts the normal physiology and cellular homeostasis of all organisms, potentially resulting in their death [1, 5]. The heat shock response, an integral part of the physiological system that protects against environmental perturbations [6], involves the synthesis of heat shock proteins (Hsps) which, by molecular chaperone activity facilitate the proper folding of nascent proteins, prevent stress-induced irreversible protein denaturation and mediate storage and refolding of partially denatured protein [4]. Hsps also appear to stimulate the innate immune response of aquatic organisms thereby shielding cells against injury due to pathogens and making them more tolerant of disease and infection [7].

Non-lethal heat shock (NLHS) is an effective method to protect aquatic organisms against stress, an outcome often associated with increased Hsp accumulation [7, 5]. NLHS increases Hsp70 in the common carp, Cyprinus carpio, allowing it to survive a normally lethal temperature [8]. NLHS of Artemia franciscana promotes Hsp70 build-up, induces thermotolerance and guards Artemia larvae against V. campbellii and V. proteolyticus, two pathogens of this branchiopod crustacean [9, 10]. Exposing Penaeus monodon to a short hyperthermic stress enhances Hsp70 accumulation and resistance against gill associated virus (GAV) [11]. The concurrent induction of heat tolerance, resistance to bacterial infection and Hsp70 synthesis, suggests a role for Hsp70 in mediating the effects of stress perhaps via chaperoning and/or immune activation [12, 1, 4].

Several issues impede sustainable production of the Asian green mussel Perna viridis [13], a major aquaculture species in Malaysia, with fluctuation in water temperature due to climate change the most serious [14–17]. Additionally, bacteria, parasites and heavy metals hinder the successful cultivation of P. viridis and other bivalves in cage culture systems [18–20]. These types of problems occur in Marudu Bay, Malaysia, where temperature changes due to an influx of water lead to secondary infections by V. alginolyticus, a common pathogen of bivalves and crustaceans, causing mortalities of 95–98% in cultured P. viridis. Oysters cultivated in the same rafting area exhibit clinical signs similar to those of P. viridis. Sessile organisms like P. viridis depend on physiological responses such as the increased synthesis of Hsps to accommodate stresses because they cannot escape by swimming [1, 21]. Thus, the synthesis of Hsp70 in P. viridis upon NLHS was investigated in this study, revealing a potential role for this protein in tolerance to heat and resistance to bacterial infection.

Materials and Methods

Culture of P. viridis

Adult P. viridis measuring 70–80 mm in length were purchased from various long-line culture farms in Masai, Johor (1°29′36.5″N 103°52′40.94″E). Animals were acclimatized in the Universiti Malaysia Terengganu Marine Hatchery under constant aeration (>6 ppt) at 28°C and salinity of 30 ppt for two weeks prior to use. During acclimation, mussels were fed daily with the microalgae Chaetoceros sp. at 6 x 10⁷ cells/ml, the final number of algae in the tank. The rearing water was replaced every 2 days.

Determination of Median Lethal Temperature (LT₅₀), and Lethal Heat Temperature (LHT) for L. viridis

To determine the minimum temperatures that caused 50% mortality (LT50) and 100% mortality (LHT) groups of 20 L. viridis acclimatized at 28°C were exposed to abrupt 30 min heat shocks ranging in temperature from 34°C to 44°C in a water bath accurate to ±0.5°C. Mussels were then transferred to 28°C and mortality was determined 24 h later by counting live animals; gaping mussels that failed to respond to gentle tapping on the shell were considered dead. The percent mortality was calculated as (N₀ - N_t)/ N₀ × 100 where N₀ and N_t are initial and final numbers of living mussels [8]. Ten mussels were tested at each temperature and experiments were done in triplicate with non-heated animals as controls.

Protein Extraction, SDS Polyacrylamide Gel Electrophoresis and Immunoprobing of Western Blots

For protein extraction approximately 100 mg of tissue prepared individually from the adductor muscle, foot, gill and mantle was rinsed with sterile, cold, distilled water several times, and homogenized in 500 μl cold buffer K (150 mM sorbitol, 70 mM potassium gluconate, 5 mM MgCl₂, 5 mM NaH₂PO₄, 40 mM HEPES, pH 7.4) [22] containing a protease inhibitor cocktail (Sigma-Aldrich Inc, USA) [5]. Two-times concentrated SDS polyacrylamide gel electrophoreses sample buffer [23] was added to equal volumes of tissue homogenate, mixed by vortexing, heated at 95°C for 5 min, cooled and centrifuged at 2200 x g for 60 sec. Ten μl samples of the supernatant containing 0.2 mg protein were loaded in individual lanes of 7% SDS polyacrylamide gels and resolved by electrophoresis at 120 V for 15 min, followed by 150 V for 45 min. Two gels were run simultaneously of which one was stained with Biosafe Coomassie (BioRad Laboratories, USA) and the other blotted to polyvinylidene fluoride transfer membrane (BioRad Immun-Blot PVDF, USA). Membranes were incubated in 50 ml of blocking buffer which consisted of phosphate buffered saline containing 0.2% (v/v) Tween-20 and 5% (w/v) bovine serum albumin. Blots were then incubated for 60 min at room temperature with a mouse monoclonal antibody (Thermo Scientific, USA, MA3-006) diluted 1:5000 in PBS (BioRad Laboratories, USA) and which recognized both constitutive and inducible Hsp70. Goat anti-mouse IgG coupled with horseradish peroxidase (HRP) conjugate (Affinity BioReagents Inc., Golden, CO) was employed at a dilution of 1:5000 in PBS as secondary antibody. Diaminobenzidinetetrahydrocloride dehydrate (DAB) at 0.7 mM was used in association with 0.1% (v/v) H₂O₂ in 0.1 M Tris-HCl, pH 7.6, for detection of antibody reactive proteins [22, 10]. Human recombinant Hsp70 (Sigma Aldrich Inc.-H7283, USA) served as control for antibody reactivity. The blots were scanned with a GS-800 calibrated densitometer (BioRad Laboratories, USA) and quantification was performed by measuring the bands for PvHsp70-1 and PvHsp70-2 with Quantity One software (BioRad Laboratories, USA). The amounts of Hsp70 in tissues of P. viridis exposed to NLHS were interpreted as reflective density/mm², the density value generated by Quantity One software. Human Hsp70 served as the control for antibody specificity.

Determination of NLHS

Adult mussels (n = 5) acclimated at 28°C were abruptly heat shocked at temperatures ranging from 30 to 40°C for 30 min and then transferred to 28°C for 6 h recovery prior to protein extraction. Mussels held at 28°C served as controls. As determined by SDS polyacrylamide gel electrophoresis and immunoprobing of western blots the temperature that induced maximum Hsp70 accumulation in mussel tissues and did not result in mussel mortality was 38°C. In subsequent experiments, adult mussels (n = 30) acclimated to 28°C were heated at 38°C and allowed to recover at 28°C for 0, 6, 12, 24 and 48 h prior to protein extraction. After 48 h, protein was extracted every 2 days until 10 days post-heat shock. Determination of Hsp70 band density on Western blots, heat shock parameters and recovery conditions established that the optimal conditions for NLHS of P. viridis were 30 min heat shock at 38°C followed by 6 h recovery at 28°C, a value used in subsequent stress experiments.

Identification of Hsp70 by Mass Spectrometry

In preparation for liquid chromatography-tandem mass spectrometry (LC-MS/MS) (Wischgoll et al., 2009), protein samples from mussels receiving NLHS were resolved in 5% SDS polyacrylamide gels by electrophoresis, stained with Biosafe Coomassie (BioRad Laboratories) and destained. Gel slices containing PvHsp70-1 and PvHsp70-2 were excised and freeze-dried overnight. Proteins were then digested with trypsin and the extracted peptides [24] were loaded onto a C18 column 300SB, 3.5 μm column (Agilent Technologies, USA) and separated with a linear gradient of water/acetonitrile/0.1% formic acid (v/v). The peptides were analyzed by electrospray ionization mass spectrometry with a Shimadzu Prominence Nano HPLC system (Shimadzu, Japan) coupled to a 5600 TripleTOF mass spectrometer (AB Sciex, USA). Protein identification was performed with Mascot sequence matching software (Matrix Science, USA) and the Ludwig NR database.

NLHS and the Induction of Heat and Bacterial Tolerance in P. viridis

Thermotolerance induction was determined by challenging mussels exposed to NLHS at their LT50 and LHT with survival ascertained 24 h later as described above. Ten mussels were used for each treatment and experiments were done in triplicate. Control animals were held at 28°C.

To determine LC50, the concentration of V. alginolyticus causing 50% mortality of mussels, bacteria were grown overnight at 28°C with constant shaking in marine nutrient broth to stationary phase, harvested and suspended in sterile seawater prior to determining density at 600 nm. The number of bacteria was calculated from a standard curve obtained according to the equation, y = (2 x 10⁸)x – (3 x 10⁷), where y is the number of bacteria/ml and x is the OD₆₀₀ value. Mussels were incubated by immersion with 1 x 10⁶, 1 x 10⁷, 1 x 10⁸ and 1 x 10⁹ V. alginolyticus/ml for various times. Survival was determined daily by counting live animals. Gaping mussels that failed to respond to gentle tapping on the shell were considered dead. The experiment was done in triplicate.

Mussels (n = 10) subjected to NLHS were challenged with 1 x 10⁸ V. alginolyticus/ml, for 72 h, the LC₅₀, after which survival was determined as described in the previous section. Mussels challenged with V. alginolyticus without NLHS served as controls. The experiment was done in triplicate.

Data Analysis

Survival percentages were ArcSin-transformed to satisfy normality. The significance of differences between survival of groups of challenged mussels either exposed or not exposed to NLHS and the amounts of Hsp70 were evaluated by using one way ANOVA with SPSS version 20.0 for Windows.

Results

LT₅₀ and LHT for Adult P. viridis

Heating for 30 min at temperatures ranging from 34°C to 40°C did not kill adult P. viridis but mortality occurred above 40°C, with LT₅₀ and LHT at 42°C and 44°C respectively (Fig 1).

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Fig 1. LT₅₀ and LHT for P. viridis.

The mortality of P. viridis adults acclimatized at 28°C and heat shocked for 30 min at 1°C intervals was determined as described in Methodology. LT₅₀, median lethal heat treatment; LHT, lethal heat treatment. Experiments were done in triplicate. Data are presented as mean ± standard errors.

https://doi.org/10.1371/journal.pone.0135603.g001

Heat Shock Induced Hsp70 in P. viridis

Following 6 h recovery 70 kDa proteins were observed when extracts of adductor muscle, foot, gill and mantle from P. viridis heated at temperatures from 28–40°C were resolved in 7% SDS polyacrylamide gels and stained with Coomassie blue (Figs 2 and 3). Immunoprobing of polyvinylidene fluoride membranes containing protein extracts resolved in SDS polyacrylamide gels with a monoclonal antibody to Hsp70 revealed single 70 kDa bands at lower temperatures but two bands at higher temperatures (Fig 2). The upper band was termed PvHsp70-1 and the lower PvHsp70-2. The amount of PvHsp70-1 visible in immunostained blots increased at 34 and 36°C in adductor tissue and at 36 and 38°C in other tissues (S1 Table) (S1A Table). PvHsp70-2 was induced at 38 and slightly at 40°C in adductor muscle, whereas in foot, gill and mantle PvHsp70-2 was apparent at 36, 38 and 40°C (S1B Table). Heat shock at 40°C all but eliminated PvHsp70-2 in adductor muscle and reduced PvHsp70-1 in all organs with adductor muscle also showing a decline at 38°C. PvHsp70-1 and PvHsp70-2 protein bands on Western blots were scanned, revealing bands that were significantly different from control values (Fig 3). In the following experiments 38°C was used for heat shock because the synthesis of PvHsp70-1 and PvHsp70-2 was enhanced at this temperature in all tissues of P. viridis examined and no death of mussels occurred.

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Fig 2. Hsp70 was induced in P. viridis by heat shock.

Protein samples from the adductor muscle (A, B), foot (C, D), gill (E, F) and mantel (G, H) were resolved in 7% SDS polyacrylamide gels and either stained with Coomassie blue (A, C, E, G) or blotted to membranes and probed with antibody to Hsp70 (B, D, F, H). Arrows labeled p70 indicate the position of 70 kDa proteins in the gel. M, molecular mass markers in kDa; H-Hsp70, recombinant human Hsp70.

https://doi.org/10.1371/journal.pone.0135603.g002

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Fig 3. NLHS induced the synthesis of Hsp70 in P. viridis.

The amounts of PvHsp70-1 and PvHsp70-2 in (A) adductor muscle, (B) foot, (C) gill and (D) mantle of P. viridis exposed to heat shock at 30, 32, 34, 36, 38 and 40°C were determined by densitometry analysis of antibody-stained Western blots as described in Materials and Methods. Bars that are not visible denote the absence of PvHsp70-2. Asterisk (*) represents statistical difference against the control treatment (P<0.05). The experiment was performed in duplicate. 28, mussels not receiving NLHS (control).

https://doi.org/10.1371/journal.pone.0135603.g003

P. viridis Hsp70 Varied with Recovery Time after Heat Shock

PvHsp70-2 was induced in all tissues examined when P. viridis were heated at 38°C for 30 min followed by 6 h recovery (Figs 2, 4 and 5) (S1D Table). In adductor muscle, PvHsp70-2 declined at 12 h and was not detectable at day 2 whereas PvHsp70-1 was reduced at day 8 but still visible at day 12 (S1C Table). In foot, gill and mantle, PvHsp70-2 was present at day 4 but was difficult to detect at day 6. PvHsp70-1 decreased at either day 4 or 6 in these three tissues (Figs 4 and 5). Heat shock at 38°C for 30 min with 6 h recovery induced PvHsp70-2 in all tissues of P. viridis examined, hence these conditions were used for NLHS in subsequent experiments.

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Fig 4. P. viridis Hsp70 Varied with Recovery Time after Heat Shock.

Protein samples from the adductor muscle (A, B), foot (C, D), gill (E, F) and mantel (G, H) were resolved in 7% SDS polyacrylamide gels and either stained with Coomassie blue (A, C, E, G) or blotted to membranes and probed with antibody to Hsp70 (B, D, F, H). Arrows labeled p70 indicate the position of 70 kDa proteins in the gel. M, molecular mass markers in kDa; H-Hsp70, recombinant human Hsp70. C, mussels not receiving heat shock.

https://doi.org/10.1371/journal.pone.0135603.g004

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Fig 5. P. viridis Hsp70 Varied with Recovery Time after Heat Shock.

The amounts of PvHsp70-1 and PvHsp70-2 in the (A) adductor muscle, (B) foot, (C) gill and (D) mantle of P. viridis upon NLHS at 38°C with different recovery length were determined as just described. Data are presented as mean ± standard errors. Bars that are not visible denote the absence of PvHsp70-2. Asterisk (*) represents statistical difference against the control treatment (P<0.05). The experiment was performed in duplicate. c and 28, mussels not receiving NLHS (control).

https://doi.org/10.1371/journal.pone.0135603.g005

Identification of Hsp70 Isotypes in P. viridis by Mass Spectrometry

Although only a single prominent band was distinguished around 70 kDa in 7% SDS polyacrylamide gels (Fig 2), two bands were seen upon electrophoresis in 5% gels (Fig 6). The two bands were excised and resident proteins analyzed by mass spectrometry. The upper band contained an Hsp70 equivalent to PvHsp70-1 and the lower band an Hsp70 corresponding to PvHsp70-2. Utilization of Mascot sequence matching software with Ludwig NR database revealed that PvHsp70-1 and PvHsp70-2 were respectively most similar to Hsp70 from P. viridis and M. galloprovincialis (Table 1). Both isotypes were similar to Hsp70s in other bivalves (Table 2).

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Fig 6. Two 70 kDa protein bands were resolved in 5% SDS polyacrylamide gels.

Tissues corresponding to the adductor muscle, foot, gill and mantel were isolated from P. viridis exposed to NLHS, homogenized, centrifuged and applied to a 5% SDS polyacrylamide gel. Labeled arrows indicate excised regions of the gel subsequently shown by mass spectrometry to contain PvHsp70-1 and PvHsp70-2. M, molecular mass in kDa; C, mussels not receiving NLHS; HS, mussels receiving NLHS; F, foot; G, gill; MA, mantle; MU, adductor muscle.

https://doi.org/10.1371/journal.pone.0135603.g006

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Table 1. Identification of PvHsp70-1 and PvHsp70-2 by LC-MS/MS.

https://doi.org/10.1371/journal.pone.0135603.t001

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Table 2. Comparison of PvHsp70-1 and PvHsp70-2 with Hsp70 from bivalves.

https://doi.org/10.1371/journal.pone.0135603.t002

NLHS Promoted Thermotolerance in P. viridis

Exposure to NLHS increased the survival of mussels approximately 2-fold upon LT50 challenge whereas 50% of animals primed with NLHS were viable after LHT (Fig 7).

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Fig 7. NLHS enhanced the thermotolerance of P. viridis.

P. viridis acclimatized at 28°C were exposed to NLHS and then heated for 30 min at their LT₅₀ (42°C) and LHT (44°C). Survivors were counted 24 h after challenge. Data are presented as mean ± standard errors. Asterisk (*) represents statistical difference against the control (P< 0.05). The experiments were performed in triplicate. Non-induced, mussels not receiving NLHS; Induced, mussels exposed to NLHS.

https://doi.org/10.1371/journal.pone.0135603.g007

NLHS Increased the Tolerance of P. viridis to Bacterial Infection

Exposure of non-heated P. viridis to V. alginolyticus for 72 h revealed an LC₅₀ of 1.0 x 10⁸ bacteria/ml (Table 3). Priming P. viridis with NLHS enhanced survival upon 72 h exposure to 1 x 10⁸ V. alginolyticus/ml from 50% to almost 100% (Fig 8).

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Table 3. Survival of P. viridis adults after exposure to V. alginolyticus.

https://doi.org/10.1371/journal.pone.0135603.t003

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Fig 8. NLHS increased the bacterial tolerance of P. viridis.

P. viridis acclimatized at 28°C were exposed to NLHS, and then incubated with 1 x 10⁸ V. alginolyticus/ml, the LC₅₀ for this species. Survivors were counted 72 h after challenge. Data are presented as mean ± standard errors. Asterisk (*) represents statistical difference against the control (P< 0.05). The experiment was performed in triplicate. Non-induced, mussels not receiving NLHS; Induced, mussels exposed to NLHS.

https://doi.org/10.1371/journal.pone.0135603.g008

Discussion

The synthesis of Hsp70, the best studied stress protein, is induced in aquatic animals by heat stress [25, 4, 26] and in this work immunoprobing of western blots revealed that two Hsp70 isotypes increased in P. viridis after NLHS. The P viridis Hsp70s, PvHsp70-1 and PvHsp70-2, respectively matched Hsp70 in P. viridis and M. galloprovicialis most closely, while being similar to Hsp70s from other bivalves. PvHsp70-1 and PvHsp70-2 increased in the adductor muscle, foot, gill and mantle of P. viridis upon NLHS. Accumulation of Hsp70 in the tissues examined in this study was also seen in O. edulis, M. galloprovincialis, and C. gigas [22, 27, 28].

PvHsp70-1 was observed in mussel tissues before heat shock indicating that it was produced constitutively, whereas PvHsp70-2 was not apparent until recovery after NLHS at temperatures favourable for growth, observations similar to those for other aquatic organisms exposed to heat perturbation [9]. PvHsp70-2, the inducible isotype of Hsp70, was present in all tissues of P. viridis examined after 6 h recovery from heat shock, but shorter post-shock times were not examined so synthesis may have occurred earlier. PvHsp70-2 was induced maximally by a 30 min heat shock at 38 to 40°C, in line with findings that Hsp70 is induced when aquatic organisms experience temperatures 5–10°C above their normal growth requirement [29, 30]. PvHsp70-2 persisted for several hours after induction by NLHS perhaps providing protection against subsequent stress, but their synthesis eventually decreased as seen in other species [29]. Constitutive Hsp70, transiently induced by heating P. viridis, may function cooperatively with inducible Hsp70 to protect cells against heat, pathogens, heavy metals and other insults [31, 7, 4]. P. viridis Hsp70 may be crucial for cell survival during stress, expediting protein repair and reducing protein denaturation that could lead to death [32, 4]. In this study, a 30 min heat shock at 38°C with 6 h recovery was selected as the NLHS because this treatment increased the amount of PvHsp70-1 and PvHsp70-2 in P. viridis without causing mortality. The possibility of Hsp70 breakdown generating a second band is low because the mass-spectrometry indicated two different Hsp70s and protease inhibitors were used when making the protein extract.

Induced thermotolerance refers to the ability of an organism to withstand an otherwise lethal temperature, a condition achieved by priming animals with NLHS [8]. In this study, groups of mussels primed with NLHS and exhibiting increased Hsp70 survived LT50 challenge, whereas approximately 50% survived LHT challenge. Clearly, NLHS promoted thermotolerance in P. viridis, an observation similar to that for Mytilus edulis where exposure to a short heat shock increased resistance to lethal heat for 3 d [33]. In other bivalves, constitutively expressed and induced stress proteins are thought to mediate thermotolerance and this may require their cooperation. For example, the up-regulation of constitutive 77 and 72 kDa proteins and the synthesis of an inducible 69 kDa protein by NLHS promote thermotolerance in C. gigas [22]. Additionally, increases in constitutive and inducible Hsp70s correlate with thermotolerance induction in the adult oyster, Ostreola conchaphila, [34] and Hsp70 accumulation parallels increasing protection of A. irradians irradians juveniles against LHT, with thermotolerance lasting at least 7 days [35]. The correlation between Hsp70 accumulation and increasing thermotolerance in bivalves is observed for other aquatic organisms such as fish and shrimp [4]. These studies indicate the importance of constitutive and inducible Hsp70 isotypes in bivalve thermotolerance, however Hsps in addition to Hsp70 may contribute to thermotolerance by protecting proteins against heat denaturation and assisting protein refolding [36–38], both vital to cell homeostasis.

Cross-protection or cross-tolerance, an enhanced tolerance to a particular stress, acquired by an initial transient, but different, stress [39, 40, 7, 4], was demonstrated by challenging P. viridis subjected to NLHS with V. alginolyticus. The enhanced protection of P. viridis against V. alginolyticus correlated with increasing amounts of PvHsp70-1 and PvHsp70-2 in all tissues of P. viridis examined. A role for Hsp70 in averting infection is suggested for C. virginica where the augmentation of a constitutive 69 kDa protein and the induction of a 72 kDa protein after sub-lethal heat shock promotes survival upon challenge with Perkinsus marinus [41]. The accumulation of Hsp70 after a short heat stress corresponds to increased resistance of P. monodon against gill associated virus (GAV), an effect accompanied by reduction of viral replication [11]. Additionally, accumulation of Hsp70 after NLHS enhances the tolerance of A. franciscana larvae against pathogenic V. campbellii and V. proteolyticus (Sung et al., 2007). Clearly, the accumulation of Hsp70s induced by NLHS correlates with survival against subsequent infection, suggesting Hsp70 influences the immune response. Hsps may stabilize cells against injury in response to pathogen proliferation, mediate folding of cell proteins synthesized due to bacterial pathogens, store and re-fold partially denatured protein and stimulate the innate immune response, possibly by sending danger signals to the innate immune system [42–44, 4, 7].

Although bivalves rely solely on an innate, non-lymphoid system of immune responses [1, 45], some of the immune mechanisms in bivalves are structurally and functionally similar to those in vertebrates [46]. Hsp70 attenuates infections in vertebrates by activating toll-like receptors (TLRs) and transducing signals from inflammatory reactions to cells of the innate immune system such as macrophages, dendritic cells and neutrophils [47, 48]. The extracellular Hsp70 family promotes inflammatory cytokine production [49] and may elicit production of inducible nitric oxide synthase [50], interleukin (IL) 1-β, IL 6 and tumor necrocis factor α (TNFα) [51], to guard against infection. Invertebrate Hsps restrict bacterial infection by activation of TLRs [7], but there is no evidence indicating a relationship between Hsps and TLRs in bivalves. Considering that TLR genes occur in bivalves such as C. farreri [52], C. virginica [53], A. irradians [54] and M. mercenaria [55] immune activation via TLRs is possible in P. viridis.

The data presented herein demonstrate that Hsp70 is induced in P. viridis by NLHS and that Hsp70 plays a role in increasing the thermotolerance of P. viridis and enhancing survival against V. alginolyticus challenge. Further work is required to elucidate the role of Hsps in induced thermotolerance and the immune response of mussels, perhaps with the application of molecular tools such as RNA interference (RNAi) an option. Such studies are of fundamental interest and have applied significance through formulation of strategies to protect aquatic organisms against stress and disease, of particular importance in aquaculture.

Supporting Information

S1 Table. Amounts of PvHsp70-1 interpreted as reflective density/mm² in tissues of P. viridis exposed to NLHS.

The amounts of PvHsp70-1 in adductor muscle, foot, gill and mantle of P. viridis exposed to heat shock at 30, 32, 34, 36, 38 and 40°C were determined by densitometry analysis of antibody-stained Western blots as described in Materials and Methods. Data are presented as mean ± standard deviation. Asterisk (*) represents statistical difference against the control treatment (P<0.05). 28, mussels not receiving NLHS (control) (S1A Table). Amounts of PvHsp70-2 interpreted as reflective density/mm² in tissues of P. viridis exposed to NLHS. The amounts of PvHsp70-2 in adductor muscle, foot, gill and mantle of P. viridis exposed to heat shock at 30, 32, 34, 36, 38 and 40°C were determined by densitometry analysis of antibody-stained Western blots as described in Materials and Methods. Data are presented as mean ± standard deviation. Asterisk (*) represents statistical difference against the control treatment (P<0.05). 28, mussels not receiving NLHS (control) (S1B Table). Amounts of PvHsp70-1 interpreted as reflective density/mm² in tissues of P. viridis upon NLHS at 38°C with different recovery length. The amounts of PvHsp70-1 in the adductor muscle, foot, gill and mantle of P. viridis upon NLHS at 38°C with different recovery length. Data are presented as mean ± standard deviation. Asterisk (*) represents statistical difference against the control treatment (P<0.05). c and 28, mussels not receiving NLHS (control) (S1C Table). Amounts of PvHsp70-2 interpreted as reflective density/mm² in tissues of P. viridis upon NLHS at 38°C with different recovery length. The amounts of PvHsp70-1 in the adductor muscle, foot, gill and mantle of P. viridis upon NLHS at 38°C with different recovery length. Data are presented as mean ± standard deviation. Asterisk (*) represents statistical difference against the control treatment (P<0.05). c and 28, mussels not receiving NLHS (control) (S1D Table).

https://doi.org/10.1371/journal.pone.0135603.s001

(DOCX)

Acknowledgments

We thank Mimi Iryani, Universiti Malaysia Terengganu, for her contributions to this study. This work was supported by E-Science Fund No: 04-01-12-SS0109 from the Ministry of Science, Technology and Innovation (MOSTI), Malaysia to MEAW, an Exploratory Research Grant Scheme (ERGS) No. 55090 from the Ministry of Higher Education, Malaysia to YYS and a Natural Sciences and Engineering Research Council Discovery Grant to THM.

Author Contributions

Conceived and designed the experiments: YYS MEAW NAA. Performed the experiments: NAA. Analyzed the data: NAA YYS THM MEAW. Contributed reagents/materials/analysis tools: MEAW YYS. Wrote the paper: NAA YYS THM MEAW.

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Figures

Abstract

Introduction

Materials and Methods

Culture of P. viridis

Determination of Median Lethal Temperature (LT50), and Lethal Heat Temperature (LHT) for L. viridis

Protein Extraction, SDS Polyacrylamide Gel Electrophoresis and Immunoprobing of Western Blots

Determination of NLHS

Identification of Hsp70 by Mass Spectrometry

NLHS and the Induction of Heat and Bacterial Tolerance in P. viridis

Data Analysis

Results

LT50 and LHT for Adult P. viridis

Heat Shock Induced Hsp70 in P. viridis

P. viridis Hsp70 Varied with Recovery Time after Heat Shock

Identification of Hsp70 Isotypes in P. viridis by Mass Spectrometry

NLHS Promoted Thermotolerance in P. viridis

NLHS Increased the Tolerance of P. viridis to Bacterial Infection

Discussion

Supporting Information

S1 Table. Amounts of PvHsp70-1 interpreted as reflective density/mm2 in tissues of P. viridis exposed to NLHS.

Acknowledgments

Author Contributions

References

Determination of Median Lethal Temperature (LT₅₀), and Lethal Heat Temperature (LHT) for L. viridis

LT₅₀ and LHT for Adult P. viridis

S1 Table. Amounts of PvHsp70-1 interpreted as reflective density/mm² in tissues of P. viridis exposed to NLHS.