Environmental stress upon hepatopancreatic cells of freshwater prawns (Decapoda: Caridea) from the floodplain of Paraná River

doi:10.4236/ns.2010.27094

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Vol.2, No.7, 748-759 (2010) Natural Science

http://dx.doi.org/10.4236/ns.2010.27094

Environmental stress upon hepatopancreatic cells

of freshwater prawns (Decapoda: Caridea)

from the floodplain of Paraná River

Pablo Collins

Instituto Nacional de Limnología (CONICET-UNL) Ciudad Universitaria, Pje El Pozo s/n, 3000 Santa Fe Santa Fe Argentina TE

0054-0342-4511645 int 113, Fac. de Bioq. y Cs. Biol. UNL, Fac. de Tecnología y Ciencias, UADER; pcollins@arnet.com.ar

Received 10 March 2010; revised 11 April 2010; accepted 17 April 2010.

ABSTRACT

In order to evaluate the influence of stressed

environments on hepatopancreatic cells of fre-

shwater prawns, Macrobachium borellii Nobili,

1896 and Palaemonetes argentinus Nobili 1901,

(Crustacea, Decapoda, Palaemonidae) were

collected at three different aquatic environ-

ments with different relationship to urban de-

velopment in Argentina. Furthermore the effects

of several cypermethryn concentration on hepa-

topancreatic cell of M. borellii and P. argentinus

were evaluated in a laboratory assays. The “N°

1” lake (Santa Fe Argentina) which is more af-

fected by the anthropogenic pressure and “Don

Felipe” lake which is still not strongly by human

activities were the studied sites from the flood-

plain of Paraná river. While Alejandra lake was

the intermedia effects sites. Different damaged

ultrastructures were found in F- and R-cells of

prawns in the stressed lake. The predominant

features were: disrupted the microvillous border,

swelled mitochondria, reduction of endoplasmic

reticulum, dyctiosomes, glycoproteins, desna-

turalization of vacuole membrane and prema-

ture autolysis. Moreover the F-cell number was

higher in the environment near to city than in

the others sites. Similar effects were observed

in the cypermethryn assays. The observations

clearly indicate that the ultrastructure of midgut

gland in the both palaemonids varies depending

on the site from which animals are collected and

the biocid presence. So, in this case it can be

stated that the hepatopancreas histology of fre-

shwater prawns is a good tool to monitor the

impact of a stressed environment upon fresh-

water prawns.

Keywords: Palaemonidae; Midgut Gland; Shrimp;

Hepatopancreas; Environmental Stress

1. INTRODUCTION

Freshwater prawns are an important and abundant group

in the floodplain of the Paraná River, mainly the species

Macrobrachium borellii Nobili, 1896 and Palaemonetes

argentinus Nobili, 1901. Both prawns have as habit the

lotic and lentic environment from La Pampa region, Ar-

gentina [1]. This area is characterized by intensive farm-

ing, and urban-industries development. Thus the aquatic

environment gathers several elements which affect the

quality of the rivers and lakes, mainly at the rain events

[2]. The nutrient increase, toxins presence and others

xenobiotic input, such as biocid and heavy metals, pro-

voke changes in the normal conditions that according to

inflow regime (sewage of various degree of treatment,

thermal regime, weather conditions and land use) affects

the quality conditions of the receptors [3,4].

In the last decades there have been many studies about

the influences of exogenous factors upon crustaceans,

being the majority of these researches made as labora-

tory tests. Such works revealed important basic data, and

it can be refered to in case of evaluating the environ-

mental influences upon hepatopancreas. There exists a

close correlation with different kind of stresses and the

ultrastructure of hepatopancreas [5-17]. Some products

and/or household waste, such as industrial discharges,

pesticides or sewage are transformed and degraded

through various reactions with other biotic and abiotic

components, when they get into the river. These ele-

ments may alter the hepatopancreatic cells and it could

be used as biological markers so as to assess the toxic

properties of the environmental contaminants [18-20].

The aim of the present work is to compare the ultra-

structure of the hepatopancreatic cells of M. borellii and

P. Collins / Natural Science 2 (2010) 748-759

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P. argentinus freshwater prawns at three natural enviro-

nments with different quality water, in relationship with

the biocid use, human activities or land use.

2. MATERIALS AND METHODS

2.1. Sampling Prawns

Juveniles, males and females of M. borellii and P. argen-

tinus (Crustacea, Decapoda, Palaemonidae) were sam-

pled in the lakes “Don Felipe” (31° 39' S, 60° 41' W),

“Alejandra” (31° 45' S, 60°31' W) and “N° 1” (31° 40' S,

60°30' W) (Santa Fe, Argentina) during a time of low

and high water phases of the flooding cycle (winter and

summer, respectively) (Figure 1), and they samples

were immediately taken to laboratory.

2.2. Sites of Study

The three lakes are placed in the Paraná River floodplain,

and they have different relations with human activities

and land use. In this river, the water level declined from

summer to winter, with a new flooding pulse in spring.

They have an average annual discharge of 18,000 m³/s

and a peak of 60,000 m³/s [21]. The flooding water of

the lentic bodies in the alluvial valley dilutes the biotic

densities of the communities, and during the isolation or

low water phase these concentrations recover rapidly.

The animal densities show important oscillations am-

ong the lakes depending on its volume, distance to the

river, amplitude-longitude of flooding pulse and time of

water residence [22-24].

“Don Felipe” is an oxbow lake close to the Colastiné

River which is a secondary branch directly connected to

the main channel (Figure 1). This fact changes its vol-

ume depending on the input of water flow from the Co-

lastiné River. In the isolated phase, its maximum and

mean depth is 2 m and 0.66 m respectively [25]. The

main industrialized cities occur about 400 km away from

studied site. Most of the wasted material (e.g. from food

industries) are rapidly dissolved when it reaches the

flood valley.

“Alejandra lake” is an overflow lake with a direct

connection to the Coronda River with a total length of

900 m, 1.8 m depth and it has an area of 75,000 m2 ap-

proximately (Figure 1). The land use near this lake is

low with a scarce impact on the environment. It is a

weekend residential area but it is near to Santa Fe and

Santo Tome cities.

“N° 1” is an abandoned meander scroll lake (Figure 1)

with a 0.55 m depth average during the isolated phase

(Collins, unpublished) located close to the Salado river

(a river with high dissolved contents salt), and its vol-

ume changes depending on the input of water flow from

the Salado and Santa Fe rivers. During the high water

period, the water Salado River is retained by the Paraná

system. The Salado River passes through a series of in-

dustries and farmlands in which biocides and fertilizers

are applied upon them. Moreover industrial discharges

and waste-water emitted from the cities (Santa Fe and

Santo Tomé) are poured into the last sections of the river.

2.3. Measurement of Water Parameters

The target variables to analyze in each sampling event

were taken in the top layer and three meters from the

coast line. These were water temperature; conductivity;

pH; transparency; nitrate; ammonia; orthophosphate;

dissolved oxygen; demand biological of oxygen 5

(DBO5); glyphosate; lead and copper. The samples

were collected in polyethylene bottles and preserved at

2-4ºC to posterior analysis in some cases. Temperature,

conductivity, pH and dissolved oxygen were taken in

situ with digital sensors (Hanna HI9143, HI991003,

HI9033). Transparency was measured with Secchi disc.

All the analytical methods, conformed to EPA methods

[26] or Standard Methods [27], were determined by a

spetrophotometer Metrolab330 (nitrate; ammonia; or-

thophosphate), a spetrophotometer Perkin Elmer (limit

4 ug/L) (heavy metals) and with a high precision liquid

cromatography (limit 0.2 ug/L) (biocid). The parame-

ters were sampled weekly in a month during summer

and winter.

2.4. Hepatopancreatic Cells Evaluation with

TEM

Dissections of the midgut glands were done for three

juveniles, males and females of both prawns (M. borellii

and P. argentinus) in intermolt stage according to Drach

and Tchernigovtzeff [28] from the three lakes. Adults

without gonadal maturation evidence were used. Disse-

ctions were conducted under a binocular microscope and

placed in 2% cold glutaraldehyde solution at pH 7.4 for

2 hr at 1-4°C. The tissues were then washed in several

changes of Sörensen buffer followed by postfixation in

2% osmium tetroxide solution for 2 hr at 1-4°C. After

dehydration in graded ethilic alcohol the material was

embedded in (ERL) araldite resin. Sections with gold

interference colours were obtained using a Reichert-Jung

Ultramicrotome with a glass and a diamond knife and

then mounted on coated copper slot grids. The hepato-

pancreas sections in the grids were then double stained

in uranyl acetate (saturated solution in 70% methanol, 4

h) followed by lead citrate (5 min) and viewed in a Sie-

mens Electron Microscope 101. The cell types were

identified and quantified in each observed section (5 for

each specimen).

P. Collins / Natural Science 2 (2010) 748-759

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Figure 1. Study sites in the floodplain of Paraná Medio River (Santa Fe, Argentina). A) Main rivers and cities

indicating the three sampling environments (1: Don Felipe, 2: N° 1, 3: Alejandra). B) Main rivers in the de la

Plata Systems. C) Seasonal variation of water level in the Paraná Rriver (Santa Fe port limnigraph) (arrows

indicated the sampling time).

P. Collins / Natural Science 2 (2010) 748-759

751

2.5. Laboratory Assays

In order to evaluate on the hepatopancreatic cell of the

prawns the effects of cypermethrin, an extensively bio-

cid used in the farms and urban region, was done a labo-

ratory assays. The biocid was used in its commercial

form (Sherpa®: cypermethrin). Prawns (M. borellii and

P. argentinus) were kept in plastic containers of 0.9 m2

and 40 l with a density of 55 ind/m. The nominal sub-

lethal concentrations (cypermethrin (CY): 0.01; 0.001

and 0.0001 µg CY/l) [29] were applied only once. The

protocol was: first a continuous flow of water without

biocid of 1 ml/s during 15 days in all containers. After

that, the solutions with biocid were applied in the same

flow rate (1 ml/s) during one day. Later on the flow re-

turned to water without cypermethrin. The control group

was treated the similar forms in order to flow rate and

experience time. The prawns were daily fed with fish

muscle “ad libitum” and the mortality was registered in

all containers. The experience lasted 45 days. Each

seven day, the prawn hepatopancreas in intermolt phase

were dissected, and they were processed by a routine

histological method (dehydrated in alcohol series and

embedded in paraffin wax). They were cut into thin sec-

tions of 6 μm thickness by a rotative microtome. The

hystological cuts of these organs were stained with

haematoxylin and eosin to observe of the biocide effects

in the light microscope (5 cut for each prawns). The

hepatopancreatic cells were identificated and quantifi-

cated.

2.6. Data Analysis

Water quality parameters of each environment were

compared with ANOVA and Tukey post-test. In the same

way, differences in hepatopancreatic cell number were

evaluated with ANOVA. In the assays, survival and he-

patopancreatic cell data from control and experimental

groups were analysed with ANOVA in conjunction with

Tukey post-test too. All data were previously evaluated

to normality and homoscedasticity [30].

3. RESULTS

3.1. Environment Quality

In all the lakes, significant differences (ANOVA p < 0.05)

were registered for some parameters and sampling time

(Table 1), being the conductivity in “N° 1” lake (near

the Salado River) the highest unlike. Furthermore, these

differences were high for both sampling periods, with a

decrease values in summer during flooding period (Ta-

ble 1). The pH was not similar among all the sites, but

differences between floods and drought phases occur

only in the environment near to the Coronda River. Dis-

solved oxygen did not differ in the three lakes, being the

values lower during winter. Nutrients, such as ortho-

phosphorous, were different between Don Felipe and the

other lakes, corresponding high values in summer (Table

1). Nitrate values got the highest level in the Coronda

River (Alejandra lake). The unlike data of winter and

summer were not relevant (p > 0.05). Ammonia concen-

tration oscillated from 0.006 (Don Felipe summer) to

0.069 (N° 1 winter), showing difference between sam-

pling time. The unlike values among sites was not sig-

nificantly (Table 1). DBO5 was bigger in the environ-

ment near the Coronda River, receiving its water from

the Salado and Santa Fe Rivers (Figure 1). In summer,

all lakes have a distinct DBO5 but without statistically

significance, except in Don Felipe lake. In low water

phase (Table 1), glyphosate, residues of glyphosate, and

lead were registered in the N° 1 lake near the Santa Fe

and Santo Tomé cities.

Table 1. Mean and standard deviations of environmental parameters measured in the three lakes (Don Felipe, N° 1 and Alejandra

lakes) and two sampling times.

Don Felipe lake N° 1 lake Alejandra lake

winter summer winter summer winter summer

Temperature °C 14.8 ± 1.63 b 23.7 ± 1.11 b 13.6 ± 1.56 b 23.8 ± 0.97 b 14.7 ± 1.12 b 23.9 ± 1.12 b

Conductivity μS cm-1 150 ± 30.3a b 104 ±19.3 a b 5580 ± 1337.9 a b994 ± 29.8 a b 261 ± 55.2 a b 128 ± 17.3 a b

Transparency cm 27.5 ± 2.38 b 16.7 ± 3.79 b 29.5 ± 3.00 b 16.7 ± 3.79 b 31.8 ± 7.89 b 13.0 ± 5.29 b

pH 6.9 ± 0.29 a 6.7 ± 0.05 a 7.7 ± 0.20 a 7.5 ± 0.14 a 7.3 ± 0.12 a b 6.8 ± 0.08 a b

Dissolved oxygen ml l-1 8.8 ± 1.20 b 6.4 ± 1.09 b 9.2 ± 0.60 b 5.9 ± 2.69 b 9.6 ± 1.23 b 7.9 ± 0.29 b

DBO5 ml l-1 3.1 ± 1.68 ab 1.8 ± 0.69 ab 3.3 ± 2.25 a 3.7 ± 0.52 a 4.5 ± 4.96 a 4.2 ± 0.87 a

nitrate mg l-1 1.5 ± 0.28 1.8 ± 0.25 1.5 ± 0.61 1.5 ± 0.31 2.3 ± 1.20 2.8 ± 1.31

ammonia mg l-1 0.026 ± 0.018 b 0.009 ± 0.006 b0.037 ± 0.028 b 0.013 ± 0.015 b0.023 ± 0.017 b 0.012 ± 0.002 b

orthophosphate mg l-1 1.6 ± 1.06 a 1.1 ± 0.62 a 0.7 ± 0.27 a b 2.1 ± 0.20 a b 0.6 ± 0.64 a b 2.6 ± 0.33 a b

glyphosate* μg l-1 < 0.2 < 0.2 3.2 < 0.2 < 0.2 < 0.2

Pb μg l-1 < 4 < 4 49 < 4 < 4 < 4

Cu μg l-1 < 5 < 5 55 7.2 < 5 < 5

Significant differences according to ANOVA and Tukey post test (p < 0.05) a) among environment; b) between sampling times; *glyphosate and their

metabolite (AMPA).

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3.2. Hepatopancreatic Cells

There have been alterations in the midgut glands of ju-

veniles, males and females of both prawns species from

“N° 1” lake of Los Sapos island near Santo Tomé and

Santa Fe cities and Alejandra lake. The variability of the

damage degree was important. This depended on the

prawn origen, and the seasons (low and high water level

and temperature). The major alterations for both prawn

species were observed in the F- and R-cells, and the per-

centage of the cell type was differed from those prawns

in Don Felipe lake (mainly F-cell) (Table 2). Some pra-

wns from Alejandra lake show similar alterations than

those from N° 1 lake. The difference was observed in the

affected cell number, and/or in the intensity of the altera-

tion. Both prawn species showed similar hepatopan-

creatic cell frequency in all lakes and seasons (Table 2).

In apical zone of the alterated F-cells showed a dam-

aged microvilli border. The endoplasmic reticulum

(Figure 2(f)) and the mitochondria were more abundant

and swelled, and the cristae of the last was damaged and

increased in number compared with the mitochondria of

those prawns from Don Felipe lake. Endoplasmic re-

ticulum was either broken up into vesicles and/or exhib-

its dilated profiles (Figures 2(a), (c), (f), (h) and (i)).

The glycoproteins granules and others organelles were

increased too, e.g. in the basal region. Amorphous cor-

puscles with high electron density were found in the

cytoplasm (Figures 2(a), (b), (f) and (g)). In the most

affected F-cells (mainly in N° 1 lake) organelles lysis,

including cell nucleus were observed without breaking

the wall cell (Figures 2(b), (d) and (g)). The normal

F-cells (M. borellii and P. argentinus) belonging to “Don

Felipe” lake showed abundant rER without dilated pro-

files in the apical zone. The organelles have a homoge-

neous distribution, e.g. the cytoplasm contains glyco-

protein (or free ribosomes), peroxisomas, vesicles and

few and small mitochondria. In the basal region, it is

more frequently found the presence of Golgy systems

with distended cisterns, and surrounded by small and

dense vesicles.

The R-cells of prawns from N° 1 and Alejandra lakes

were affected in similar ways. The main alterations were:

in the apical zone of R-cells, the microvilli border was

somewhat shortened and sometimes it lacked the micro-

villar core filaments (Figures 3(a), (b) and (e)). The

endoplasmic reticulum was disrupted and the number of

residual bodies increased. The mitochondria were swell-

ed and sometimes its walls became deteriorated (Figures

3(b), (e), (f) and (g)). The lipid vacuole had an abrading

multilayered membrane (Figures 3(b) and (e)). Material

with high electron density was observed near this vacu-

ole in the apical zone (Figure 3(a)). R-cells with pre-

mature autolizing appearance were frequent (Figures

3(d), (f) and (g)). In the basal region, there were few

glycoprotein granules, and only the mitochondria was

increased and swelled, and its cristae was damaged

(Figures 3(c), (d) and (g)). The normal R-cells of

prawns from Don Felipe Lake have in apical zone a

large number of mitochondria, vesicles and glycoprotein,

which are prolonged in concentrated below the apical

plasma membrane. The undamaged microvillous border

was regular in all the extensions. In the basal region endo-

plasmic reticulum (rER and sER), glycoprotein granules

and many mitochondria were observed. The B-cells did

not show alterations that differ from the normal of hepa-

topancreatic cell cycles (Figures 4(a) and (b)) except af-

fections in some B-cells, main in N° 1 lake, where auto-

lising of organelles were registered (Figures 4(c) and (d)).

Other changes, such as basophyles vacuole groups and

differents residuals bodies, were observed in apical zone

of the F-cells in both species. Moreover, evident autolis-

ing of the organelles (Figures 5(a), (b) and (e)) and in-

definable elements associated with residuals bodies in

R-cells with abundant and distended cisterns of endo-

plasmic reticulum were frequent in the studied species

from N° 1 lake (Figures 5(c) and (d)).

3.3. Low and high water Level and

Temperature

The alterations were detected for both seasons and in the

same studied sites. The highest number of damaged cell

was registered in winter with low water level and tem-

Table 2. Hepatopancreatic cell frequency of two prawns and three lakes (Don Felipe, N° 1 and Alejandra lakes) during two sampling

times (winter and summer) (540 total observed sections).

Don Felipe lake N° 1 lake Alejandra lake

M. borellii winter summer winter summer winter summer

F-cell 29 ± 1.6 a 32 ± 1.1 a 49 ± 6.6 ab 43 ± 5.7 ab 38 ± 2.2 a 39 ± 6.1 a

R-cell 35 ± 3.3

a 39 ± 4.3 a 25 ± 5.9 a 23 ± 6.8 a 32 ± 5.2 a 37 ± 4.6 a

B-cell 36 ± 2.8 ab 29 ± 1.9 ab 26 ± 3.4 ab 34 ± 7.9 ab 30 ± 8.9 ab 24 ± 2.0 ab

P. argentinus

F-cell 32 ± 6.3 ab 25 ± 3.1 ab 54 ± 5.6 ab 46 ± 4.7 ab 36 ± 3.2 a 33 ± 1.2 a

R-cell 37 ± 5.3 a 43 ± 4.3 a 23 ± 3.9 ab 31 ± 4.8 ab 32 ± 5.5 a 37 ± 4.6 a

B-cell 31 ± 2.3 a 32 ± 3.7 a 23 ± 3.0 a 23 ± 6.3 a 32 ± 4.7 a 30 ± 1.2 a

Significant differences according to ANOVA and Tukey post test (p < 0.05). a among environment; b between sampling times.

P. Collins / Natural Science 2 (2010) 748-759

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Figure 2. F-cell of Macrobrachium borellii and Palaemonetes argentinus from Alejandra (a and f re-

spectively) and N°1 lakes (b and g resepctively). Apical cell zone of M. borellii in N° 1 lake with lysis

appearence of mitchondria, endoplasmic reticulum and glycoprotein granules (d). Basal zone of F-cell in

M. borellii (c) sampled at Alejandra and P. argentinus cell (h and i) from both lakes with vesicles, golgi

bodies and glycoprotein granules, endoplasmic reticulum forms cistern and vacuolizing dictyiosomes.

Abbreviations: F-cell (F), rough endoplasmic reticulum (rer), golgi bodies (g), high electron density

corpuscles (ac), lumen cell (l), microvillous border (mb), mitochondria (m), vesicles (v), ribosomes (r),

peroxisomes (p), nucleus (n), wall cell (w). Bars: 0.1 μm approximately.

Figure 3. R-cell of Macrobrachium borellii and Palaemonetes argentinus affected in different levels from

Alejandra and N° 1 lakes. Apical zone with microvillous border deteriorated, endoplasmic reticulum and

shortened and mitochondria swelled, small vesicles, high electron density corpuscles and lipid vacuole with

a multilayered membrane disrupted (a, b, e, f). Basal zone with endoplasmic reticulum vesiculated (rER

and sER), glycoprotein granules and mitochondria swelled (in some R-cells were found a disrupted wall

mitochondria) or with lysis appearance (c, d). Abbreviations: R-cell (R), rough endoplasmic reticulum (rer),

smooth endoplasmic reticulum (ser), high electron density corpuscles (ac), lipid vacuole (li), microvillous

border (mb), mitochondria (m), ribosomes (r), nucleus (n), wall cell (w). Bars: 0.1 μm approximately.

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Figure 4. B-cell of Macrobrachium borellii and Palaemonetes argentinus from Alejandra and N° 1

lakes. Two moment of cell cycle without stress evidence (a, b) but in some cell was observed organ-

elles autolysis in cytoplasm (c, d). Abbreviations: B-cell (B), rough endoplasmic reticulum (rer),

smooth endoplasmic reticulum (ser), autosomes (au), lumen cell (l), microvillous border (mb), mito-

chondria (m), vesicles (v), lisosomes (ly), wall cell (w). Bars: 0.1 μm approximately.

Figure 5. Others hepatopancreatic cell evidence of stress in Macrobrachium borellii and Palae-

monetes argentinus from Alejandra and N° 1 lakes. Apical zone of F-cells with undefinible resid-

ual bodies and organelles autolysis. (a, b, e) In R-cells with differents vesicles without lipid con-

tent and swelled endoplasmc reticulum (c, d, e). Abbreviations: F-cell (F), R-cell (R), rough endo-

plasmic reticulum (rer), residual bodies (rb), microvillous border (mb), mitochondria (m), vesicles

(v), wall cell (w). Bars: 0.1 μm approximately.

P. Collins / Natural Science 2 (2010) 748-759

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perature (Table 2). The percentage of affected prawns

was not different (ANOVA p > 0.005) between the species

M. borellii and P. argentinus. The “N° 1” lake had the

highest percentage of alterated cells in prawns with 75%,

32% in Alejandra lake and only 9% in Don Felipe lake

approximately. In this last one, the alterations coincided

with the observations indicated as starvation effects (lipid

dropplets with multilayered wall in R-cells). Moreover,

the cell type frequency varied with the prawn origen (Don

Felipe, N° 1 and Alejandra lakes), being the frequency of

F-cells higher in prawns from N° 1 lake during samples of

winter than other origin (Table 2).

In summer the number of affected cells disminished in

all the lakes (45 % in “N° 1” lake, 26% in Alejandra lake

and only 2% in Don Felipe lake approximately), and the

cell type frequency was similar (Table 2).

3.4. Laboratory Assays

In both prawns, damaged hepatopancreatic cells by the

pyretroid have had a relationship with the tested concen-

trations, being the cell frequency in each tested concen-

trations differents with the control at the end of the ex-

perience (ANOVA F(0.05, 2, 22) = 11.31; p < 0.0021).

The F-cells were more abundant than all the others

(Figure 6). The difference among C2, C3 and control, in

the F-cell percentage, occurred during the second week

whereas in the C1 it was in the third week (Figure 6). In

the experience, the F-cell presence oscillated with

changes significant among treated groups (Tukey’s p >

0.05). The B-cell percentage in all cypermethrin concen-

trations were low, 12% (C1) and 19% (C3).

Prawn survivals in treated groups varied significantly

during the 35 days of assays (ANOVA F(0.05, 2, 22) =

350.64; p < 0.0001, Tukey`s p < 0.05), and in the control

group there had low mortality (Figure 6)

4. DISCUSSION

The hepatopancreas of both freshwater prawns (M.

borellii and P. argentinus), which consists of four cell

types, undergoes ultrastructural changes depending on

the quality of the environment. This fact was observed in

the F-, R- and B-cells in different intensities. In these

cells, microvilli border, endoplasmic reticulum and mi-

tochondria were the most affected ultrastructure together

with and the increase of residual bodies number. More-

over premature autolysis development was observed.

On the one hand, three measured parameters have dif-

fered, being the conductivity the most variable. Trans-

parency reflected a great density of algae in the “N° 1”

lake before flooding period (November-April), which

could be due to a nutrient rise. Also, this coincides with

high DBO5 values. In the studied environments, differ-

ent algae species can produce phytotoxins, exposing the

prawns to this toxic stress. This situation could probably

activate the antioxidant defences in the hepatopancreas

leading to multiple oxidative processes and an effective

detoxification [31]. The cytoskeleton could be destroyed

by an increase in protein phosphorylation level, occur-

ring cell necrosis [32]. The immune system responds

with a melanization process which could act as a possi-

ble ROS scavenger [33]. Besides, the B-cell showed an

intracell digestion what carried out, possibly, with poste-

rior organelles degeneration in all cells, such as it was

suggested in exposed crabs to microcystins [34]. More-

over the large vacuole of B-cells contains digestive en-

zimes, e.g. cathepsin L (MeCatL) [35]. It was recognized

that in transicional cells F/B occurs P-glycoprotein

(P-gp), suggesting a function in specialized cells for ac-

cumulation and elimination of toxic compounds [36].

On the other, many substances may be toxic taking

into account their nature and amount, which are being

released by industries and cities to fresh waters and/or

the washing of farmlands during rains [37]. In these

waste waters, the heavy metals could be important quan-

titatively, and these are toxic elements for decapods [38,

39]. Moreover, these xenobiotic elements were present

in sites near to the cities, in other studies, several heavy

Table 3. Heavy metals measurements in sediment of several sites of Salado river close to the more affected sampling

area (from a work [40]).

Loc. Cu Zn Pb Cd Cr Fe Mn

1 19.54 21.29 19.47 n.d 55.18 107.1 793.05

2 0.78 0.05 1.9 n.d. 1.23 190.18 17.09

17 1.03 0.21 1.03 nd 0.64 nd 1.77

16 21.06 25.29 13.96 nd 9.71 560.92 182.26

values in µg/g; Localities: (1) Salado river in Motorway bridge (2 km up the river of “N° 1” lake approximately), (2) Salado river in Santo

Tomé-Santa Fe bridge (200 m down the river of “N° 1” lake approximately), (17) Salado river in Recreo city (10 km up the river of “N° 1”

lake, approximately), (16) Las Prusianas river in Grutly (50 km up the river of “N° 1” lake, approximately).

P. Collins / Natural Science 2 (2010) 748-759

756

Figure 6. F-cell frequency and survival percentage of

freshwater prawns (Macrobrachium borellii and Pa-

laemonetes argentinus) in the 35 days laboratory as-

says with several cypermethryn concentrations. Solid

line: control groups; dash and point line: 0.01 µg

CY/l groups; point line: 0.001 µg CY/l groups; da-

shed line: 0.0001 µg CY/l groups).

metals were registered at different points of the Salado

River sediments (Table 3), being a possible cause of

potential stress effects. Another parameter that might

provoke alterations in the prawns hepatopancreas is

temperature but this do not suggest any alteration, due to

the fact that lipid consumption for thermal stress occurs

at 29°C in M. borellii [41], and the samplings were taken

during spring (September-December) with lower tem-

peratures.

Some of the observed changes in the hepatopancreatic

cells were correlated with the starvation process and

xenobiotics effects which were described for other de-

capods [5,6,8,9,18,42,43]. The affected prawns from N° 1

lake and the assay had similar evidence of stress in the

hepatopancreas. The pyretroid is an biocid that it is used

in non-urban and urban environments, and it could po-

tentially get into the aquatic systems by different ways

(e.g. perfution, rain drenage). This could induce to ROS

production and to the formation of oxidative tissues in

the hepatopancreas of prawns, while their cells have

different biochemicals mechanisms to protect them-

selves from oxidative damage among which the glu-

tathione plays an important role [44]. Different intrinsic

factors such as specific capacity to stress tolerance, size,

nutritional condition and extrinsic factors (e.g. tempera-

ture, conductivity, ph) are important to evaluate the po-

pulational effects in a natural environment. The high

percentage of F-cells of exposed prawns to cypermethrin

could indicate that some detoxification mechanisms is

activated, including a more activity of the endoplasmic

reticulum and ribosomes in this cell type than in others.

The low number of B-cell could be interpreted as an

increase of the exoxitation of the B-cells to hepatopan-

creas lumen. Moreover another efluents, e.g. oil product

(PAH), provoked a size disminish in the hepatopancreas

cells [43]. Furthermore, cell number varies significantly

during the molt cycle (mainly, R-cell and F-cell) linked

with a change in the enzimatic activity (ATPasas and Na

/K ATPasas) [45], considering only the prawns in inter-

molt phase (c) by even.

The variation in the ultrastructure could have affected

the absorption mechanisms and protein synthesis as ob-

served by Papathanassiou and King [42]. However we

could say that these prawns can tolerate some degree of

environmental stress due to the fact that populations of

these species were found in “Laguna N° 1” lake with

similar sizes [46] to those taken from environment with

low human interference (Don Felipe lake) [25]. Thus we

can infer that there must be some detoxification mecha-

nisms such as those described by several authors [18,38,

47-51], where the F-cells could have a main rol. In these

works it was also included the capture of transuranic

elements, the deactivation of insecticides by rER or re-

moval of metals by granule formulation and its excretion

as detoxification pathways. These routes, together with

that of the complete renewal of the epithelium occurring

after several mitotic pulses [52] and/or some other me-

chanisms which involve a increase mitochondrial activ-

ity, could have allowed the presence of M. borellii and P.

argentinus in this environment.

However, the detoxification is only feasible when the

intensities of stressors do not exceed a particular thresh-

P. Collins / Natural Science 2 (2010) 748-759

757

old value, otherwise it produces cellular damage [13]

and then the point-of-no return could be reached, such as

it was observed in starved individuals of Penaeus mono-

don [9], and in this study according to the evidence in

the cypermethrin assay.

5. CONCLUSIONS

The damage cell is irreversible to live of this prawn

when the values achieved determined concentrations or

stress level. The F-cell was increased with the intensities

of the stressors such as mechanisms of detoxification.

This involves a growth in numbers and size of rER, ri-

bosomes, and mitochondria. Therefore, the reserves in

the vacuole of R-cell are used to contribute to consume

energy in the detoxification pathway. This justified the

starvation conditions that is observed in some prawns.

The midgut glands of M. borellii and P. argentinus

reacts to water quality variations, and the structural

changes in cells and tissues represent the most sensitive

level. It is showed the synergistic impact of an element,

its metabolites and other exogenous and endogenous

factors showing the hepatopancreas as a good tool in the

determination of a stress areas of the natural environ-

ment.

6. ACKNOWLEDGEMENTS

The study was supported by a grant CONICET PIP 6275 (2006-2007).

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