Crowding of white shrimp Litopenaeus vananmei depresses their immunity to and resistance against Vibrio alginolyticus and white spot syndrome virus.

Immunity parameters and the expression levels of several immune-related proteins, including lipopolysaccharide and ß-glucan binding protein (LGBP), peroxinectin (PX), intergin ß (IB), prophenoloxidase (proPO) I, proPO II, α2-macroglobulin (α2-M), cytosolic mangangese superoxide dismutase (cytMnSOD), mitochondria manganese superoxide dismutase (mtMnSOD), catalase, glutathione peroxidase (GPx), lysozyme, and penaeidin 3a were examined in white shrimp Litopenaeus vannamei reared at stocking densities of 2, 10, 20, 30, and 40 shrimp L(-1) after 3, 6, and 12 h. All immune parameters including haemocyte count, phenoloxidase (PO) activity, respiratory burst (RB), superoxide dismutase (SOD) activity, lysozyme activity, and haemolymph protein were negatively related to density and time. The PO activity, SOD activity, and lysozyme activity of shrimp reared at 10 shrimp L(-1) after 12 h significantly decreased. The transcript levels of these immune-related proteins were down-regulated in shrimp reared at 20, 30, and 40 shrimp L(-1) after 12 h. Phagocytic activity and clearance efficiency to Vibrio alginolyticus were significantly lower in shrimp reared at 30 and 40 shrimp L(-1) after 12 h. The mortality rates of shrimp reared at 20 and 40 shrimp L(-1) were significantly higher than shrimp reared at 2 shrimp L(-1) over 12-144 h and 12-48 h, respectively. Shrimp reared at high densities (>10 shrimp L(-1)) exhibited decreased resistance against pathogens as evidenced by reductions in immune parameters together with decreased expression levels of immune-related proteins, indicating perturbations of the immune system.

Shrimp that have received carrageenan via immersion and diet exhibit immunocompetence in phagocytosis despite a post-plateau in immune parameters.

The effect of carrageenan on the immune response of white shrimp Litopenaeus vannamei, was studied in vitro and in vivo. Shrimp haemocytes receiving carrageenan at 1 mg ml⁻¹ experienced change in cell size, reduction in cell viability, increase in PO activity, serine proteinase activity, and RB in vitro. Shrimp received carrageenan via immersion at 200, 400 and 600 mg L⁻¹ after 3 h and orally at 0.5, 1.0 and 2.0 g kg⁻¹ after 3 weeks showed higher proliferation of haematopoietic tissues (HPTs) together with increases in haemocyte count and other immune parameters. Shrimp that fed a diet containing carrageenan at 0.5 g kg⁻¹ after 3 weeks significantly up-regulated gene expressions of several immune-related proteins. The immune parameters of shrimp that received carrageenan via immersion and orally increased to a plateau after 3 h and after 3 weeks, but decreased after 5 h and 6 weeks, respectively. Phagocytosis and clearance of Vibrio alginolyticus remained high in shrimp that had received carrageenan via immersion after 5 h and orally after 6 weeks, respectively. Resistances of shrimp against V. alginolyticus and white spot syndrome virus were higher over 24-144 h and 72-144 h, respectively in shrimp that received carrageenan at 600 mg L⁻¹ via immersion after 3 and 5 h. It was concluded that carrageenan effectively triggers an innate immunity in vitro, and increases mitotic index of HPT, immune parameters, gene expressions and resistance against pathogens in vivo. Shrimp received carrageenan via immersion and orally exhibited immunocompetence in phagocytosis and clearance of V. alginolyticus, and resistance to pathogen despite the trend in immune parameters to recover to background values.

Vaccination enhances early immune responses in white shrimp Litopenaeus vannamei after secondary exposure to Vibrio alginolyticus.

BACKGROUND: Recent work suggested that the presence of specific memory or some form of adaptive immunity occurs in insects and shrimp. Hypervariable pattern recognition molecules, known as Down syndrome cell adhesion molecules, are able to mount specific recognition, and immune priming in invertebrates. In the present study, we attempted to understand the immune response pattern of white shrimp Litopenaeus vannamei which received primary (PE) and secondary exposure (SE) to Vibrio alginolyticus. METHODOLOGY: Immune parameters and proliferation of haematopoietic tissues (HPTs) of shrimp which had received PE and SE to V. alginolyticus were measured. In the PE trial, the immune parameters and proliferation of HPTs of shrimp that received heat-killed V. alginolyticus (HVa) and formalin-inactivated V. alginolyticus (FVa) were measured. Mortality, immune parameters and proliferation of HPTs of 7-day-HVa-PE shrimp (shrimp that received primary exposure to HVa after 7 days) and 7-day-FVa-PE shrimp (shrimp that received primary exposure to FVa after 7 days) following SE to live V. alginolyticus (LVa) were measured. Phagocytic activity and clearance efficiency were examined for the 7∼35-day-HVa-PE and FVa-PE shrimp. RESULTS: HVa-receiving shrimp showed an earlier increase in the immune response on day 1, whereas FVa-receiving shrimp showed a late increase in the immune response on day 5. The 7-day-FVa-PE shrimp showed enhancement of immunity when encountering SE to LVa, whereas 7-day-HVa-PE shrimp showed a minor enhancement in immunity. 7-day-FVa-PE shrimp showed higher proliferation and an HPT mitotic index. Both phagocytic activity and clearance maintained higher for both HVa-PE and FVa-PE shrimp after 28 days. CONCLUSIONS: HVa- and FVa-receiving shrimp showed the bacteria agglutinated prior to being phagocytised. FVa functions as a vaccine, whereas HVa functions as an inducer and can be used as an immune adjuvant. A combined mixture of FVa and HVa can serve as a "vaccine component" to modulate the immunity of shrimp.

Modulation of the innate immune system in white shrimp Litopenaeus vannamei following long-term low salinity exposure.

Immune parameters, haemocyte lifespan, and gene expressions of lipopolysaccharide and ß-glucan-binding protein (LGBP), peroxinectin (PX), integrin ß, and α2-macroglobulin (α2-M) were examined in white shrimp Litopenaeus vannamei juveniles (0.48 ± 0.05 g) which had been reared at different salinity levels of 2.5‰, 5‰, 15‰, 25‰, and 35‰ for 24 weeks. All shrimp survived during the first 6 weeks. The survival rate of shrimp reared at 2.5‰ and 5‰ was much lower (30%) than that of shrimp reared at 15‰, 25‰, and 35‰ (76%~86%) after 24 weeks. Shrimp reared at 25% grew faster. Shrimp reared at 2.5‰ and 5‰ showed lower hyaline cells (HCs), granular cells (GCs), phenoloxidase activity (PO) activity, respiratory bursts (RBs), superoxide dismutase (SOD) activity, and lysozyme activity, but showed a longer haemocyte lifespan, and higher expressions of LGBP, PX, integrin ß, and α2-M. In another experiment, shrimp which had been reared at different salinity levels for 24 weeks were challenged with Vibrio alginolyticus (6 × 10(6) cfu shrimp(-1)), and WSSV (10(3) copies shrimp(-1)) and then released to their respective seawater. At 96-144 h, cumulative mortalities of shrimp reared at 2.5‰ and 5‰ were significantly higher than those of shrimp reared at 15‰, 25‰, and 35‰. It was concluded that following long-term exposure to 2.5‰ and 5‰ seawater, white shrimp juveniles exhibited decreased resistance against a pathogen due to reductions in immune parameters. Increases in the haemocyte lifespan and gene expressions of LGBP, integrin ß, PX, and α2-M indicated that shrimp had the ability to expend extra energy to modulate the innate immune system to prevent further perturbations at low salinity levels.

An immersion of Gracilaria tenuistipitata extract improves the immunity and survival of white shrimp Litopenaeus vannamei challenged with white spot syndrome virus.

The innate immunity and resistance against white spot syndrome virus (WSSV) in white shrimp Litopenaeus vannamei which received the Gracilaria tenuistipitata extract were examined. Shrimp immersed in seawater containing the extract at 0 (control), 400 and 600 mg L(-1) for 3 h were challenged with WSSV at 2 × 10(4) copies shrimp(-1). Shrimp not exposed to the extract and not received WSSV challenge served as unchallenged control. The survival rate of shrimp immersed in 400 mg L(-1) or 600 mg L(-1) extract was significantly higher than that of challenged control shrimp over 24-120 h. The haemocyte count, phenoloxidase activity, respiratory burst, superoxide dismutase activity, and lysozyme activity of shrimp immersed in 600 mg L(-1) extract were significantly higher than those of unchallenged control shrimp at 6, 6, 6, 6, and 6-24 h post-challenge. In another experiment, shrimp which had received 3 h immersion of 0, 400, 600 mg L(-1) extract were challenged with WSSV. The shrimp were then received a booster (3 h immersion in the same dose of the extract), and the immune parameters were examined at 12-120 h post-challenge. The immune parameters of shrimp immersed in 600 mg L(-1) extract, and then received a booster at 9, 21, and 45 h were significantly higher than those of unchallenged control shrimp at 12-48 h post-challenge. In conclusion, shrimp which had received the extract exhibited protection against WSSV as evidenced by the higher survival rate and higher values of immune parameters. Shrimp which had received the extract and infected by WSSV showed improved immunity when they received a booster at 9, 21, and 45 h post-WSSV challenge. The extract treatment caused less decrease in PO activity, and showed better performance of lysozyme activity and antioxidant response in WSSV-infected shrimp.

The protective immunity of white shrimp Litopenaeus vannamei that had been immersed in the hot-water extract of Gracilaria tenuistipitata and subjected to combined stresses of Vibrio alginolyticus injection and temperature change.

White shrimp Litopenaeus vannamei which had been immersed in seawater (35 per thousand) containing the hot-water extract of Gracilaria tenuistipitata at 0 (control), 400, and 600 mg L(-1) for 3 h, were subjected to temperature transfer (28 degrees C), or combined stresses of Vibrio alginolyticus injection (2.4 x 10(6) colony-forming unit shrimp(-1)) and temperature transfer (28 degrees C) from 24 degrees C, and the immune parameters including hyaline cells (HCs), granular cells (GCs, including semi-granular cells), total haemocyte count (THC), phenoloxidase (PO) activity, respiratory burst (RB), superoxide dismutase (SOD) activity, and haemolymph protein concentration were examined 6-144 h post-transfer. Shrimp with no exposure to the extract and no temperature transfer served as the background control. Results indicated that these parameters of shrimp subjected to temperature transfer, or subjected to combined stresses significantly decreased to the lowest at 12 h post-transfer. Results indicated that these parameters of shrimp immersed in 600 mg l(-1) extract had returned to the background values at 24-144 h post-transfer, whereas these parameters of control shrimp returned to the background values at > or =144 h post-transfer. It was therefore concluded that the immunity of L. vannamei which had been immersed in seawater containing the hot-water extract of G. tenuistipitata exhibited a protective effect against temperature transfer, and combined stresses of V. alginolyticus injection and temperature transfer as evidenced by the earlier recovery of immune parameters.

Administration of the hot-water extract of Spirulina platensis enhanced the immune response of white shrimp Litopenaeus vannamei and its resistance against Vibrio alginolyticus.

White shrimp Litopenaeus vannamei which had been injected with the hot-water extract of Spirulina platensis at 6, 10, and 20 microg g(-1), or immersed in aerated seawater containing extract at 200, 400, and 600 mg L(-1) were challenged with Vibrio alginolyticus at 1.5 x 10(6) or 1.4 x 10(6) colony-forming units (cfu) shrimp(-1), and then placed in seawater. Survival rates of shrimp that received the extract of S. platensis at 6-20 microg g(-1), and those of shrimp immersed in seawater containing the extract at 400 and 600 mg L(-1) were significantly higher than those of control shrimp after 24-96 and 48-96 h, respectively. In a separate experiment, the hyaline cell (HC) count, granular cell (GC, including semi-granular cell) count, total haemocyte count (THC), phenoloxidase (PO) activity, respiratory burst (RB), superoxide dismutase (SOD) activity, glutathione peroxidase (GPx) activity, and lysozyme activity were measured when shrimp were injected with the extract at 6, 10, and 20 microg g(-1), and immersed in seawater containing the extract at 200, 400, and 600 mg L(-1). These parameters directly increased with the concentration, and significantly increased when shrimp were immersed in the seawater containing the extract at 0.5-4 h. L. vannamei that received all doses of the extract via injection or via immersion all had increased phagocytic activity and clearance efficiency to V. alginolyticus at 12-72 h and 3-4 h, respectively. It was concluded that L. vannamei that received the hot-water extract of S. platensis had enhanced innate immunity and increased resistance against V. alginolyticus infection.

Innate immunity of the white shrimp Litopenaeus vannamei weakened by the combination of a Vibrio alginolyticus injection and low-salinity stress.

White shrimp Litopenaeus vannamei were reared at a salinity of 35 per thousand without a Vibrio alginolyticus injection (unchallenged group), and other shrimp were reared at 35 per thousand, injected with tryptic-soy broth (TSB)-grown V. alginolyticus at 1.8 x 10(5) colony-forming units (cfu) shrimp(-1) (challenged group), and then examined for the hyaline cell (HC) count, granular cell (GC, including semi-granular cell) count, total haemocyte count (THC), phenoloxidase (PO) activity, respiratory burst (RB) and superoxide dismutase (SOD) activity after transfer to 35 per thousand (control), 25 per thousand, 20 per thousand, and 15 per thousand for 1, 6, 12, 24, 72, and 120 h. Results indicated that the haemocyte count, PO activity, RB, and SOD activity of unchallenged shrimp and challenged shrimp that were transferred to low-salinity levels all began to significantly decrease at 6, 6, 6, and 1 h, respectively, and reached the lowest levels at 12 h. HC, GC, the THC, PO activity, RB, and SOD activity of unchallenged shrimp that were transferred to 15 per thousand decreased by 53%, 41%, 49%, 68%, 39%, and 62%, whereas those parameters of challenged shrimp that were transferred to 15 per thousand decreased by 79%, 78%, 79%, 82%, 54%, and 72%, respectively after 12 h compared to control shrimp. These immune parameters began to recover after 24-72 h for both unchallenged shrimp and challenged shrimp. We concluded that the innate immunity was weakened in white shrimp L. vannamei that received combined stresses of a V. alginolyticus injection, and low-salinity transfer. It was also concluded that shrimp with respectively 21%, 18%, 46%, and 28% lower THC, PO activity, RB, and SOD activity of the original values would be killed due to decreases in their immunity, and resistance to V. alginolyticus infection. Shrimp farming should be maintained at a constant high salinity level to prevent exacerbated decreases in innate immune parameters of shrimp when infected by a pathogen coupled with low-salinity stress leading to mortality.

The immune response of white shrimp Litopenaeus vannamei and its susceptibility to Vibrio alginolyticus under low and high pH stress.

White shrimp Litopenaeus vannamei (also known as Penaeus vannamei) held in 34 per thousand seawater at pH 8.2 were injected with tryptic soy broth (TSB)-grown Vibrio alginolyticus at 8 x 10(5) colony-forming units (cfu) shrimp(-1), and then transferred to tanks at pH 6.5, 8.2 (control) and 10.1, respectively. After 24-168 h, the mortality of V. alginolyticus-injected shrimp that were transferred to pH 6.5 and pH 10.1 tanks was significantly higher than that of V. alginolyticus-injected shrimp held at pH 8.2. In another experiment, L. vannamei held at pH 8.2 following transfer to pH 6.5, 8.2 (control) and 10.1 for 6, 12, 24, 72 and 120 h were examined for immune parameters, phagocytic activity, and the clearance efficiency of shrimp against V. alginolyticus. The results indicated that the shrimp that were transferred to pH 6.5 and 10.1 showed significantly decreased phenoloxidase (PO) activity, respiratory burst, phagocytic activity, and clearance efficiency against V. alginolyticus over 6-72 h; significantly decreased superoxide dismutase (SOD) activity over 6-24h; and decreased total haemocyte count (THC) over 12-72 h. Shrimp transferred to pH 10.1 showed significantly decreased granular cell counts, and THC after 6h, and decreased SOD activity after 72 h. The immune parameters of shrimp transferred to pH 6.5 and 10.1 returned to the original values after 120 h. However, shrimp transferred to pH 6.5 still maintained lower phagocytic activity, and clearance efficiency against V. alginolyticus, and shrimp transferred to pH 10.1 still maintained lower clearance efficiency against V. alginolyticus. It was therefore concluded that low pH and high pH stress decrease the resistance of white shrimp L. vannamei against V. alginolyticus and decrease several parameters of the immune response.

The immune response of white shrimp Litopenaeus vannamei following Vibrio alginolyticus injection.

White shrimp Litopenaeus vannamei injected with saline, and injected with tryptic soy broth (TSB)-grown Vibrio alginolyticus at 1.0 x 10(5) and 1.8 x 10(5) colony-forming units (cfu) shrimp(-1) were examined for hyaline cell (HC) counts, granular cell (GC) counts, total haemocyte counts (THCs), phenoloxidase (PO) activity, respiratory burst (RB) and superoxide dismutase (SOD) activity after 1-168 h. Shrimp that received no injection served as the control. The shrimps which received V. alginolyticus at both doses showed significant decreases in these parameters after 6-96 h. The values for HC and SOD activity decreased earlier and then RB. The time to cause maximum depletion of haemocytes (haemocytopenia), PO activity, RB, and SOD activity were 12, 72, 48, and 24 h post-injection, respectively. The HC, GC, and RB returned to the original values earlier at 72 h, followed by SOD activity at 96 h, and then PO activity at 168 h post-infection. It was concluded that an injection of V. alginolyticus rapidly reduced the shrimp's immunity by decreasing HC, GC, SOD activity, RB, and PO activity within 3-24 h, followed by a slow recovery during 72-168 h post-injection. Furthermore, white shrimp L. vannamei which received V. alginolyticus showed a 6-9 h later response in PO activity, and a 72-96 h later recovery of PO activity, compared to the responses in RB and SOD activity indicating their roles in shrimp defence and immunity.