BIOTROPIA No. 6, 1992/1993: 33-44 

EFFECTS OF THE HEAVY METAL, ZINC, ON THE FRESHWATER FISH 

TILAPIA NILOTICA L. 

VIRGINIA S. CARING 
Institute of Biology, University of the Philippines,  

Diliman, Quezon City, Philippines 

ABSTRACT 

Gills, gonads, and blood of Tilapia nilotica exposed to different concentrations of zinc sulfate (ZnSO4. 

7H2O) exhibited histological effects. Gills of posthatch larvae exposed chronically for 21 days to 2 ppm zinc 

sulfate and fingerlings to 10 ppm sublethal zinc concentrations exhibited hyperplasia that resulted in fusion of 

adjacent secondary gill lamellae. The same effects were observed in 4-hour short-term exposure to 30 ppm 

lethal dose. 
Posthatch larvae subjected to 2 and 5 ppm sublethal levels of zinc for 30 days retained 

undifferentiated gonads with differentiation with oogonial proliferation. Ovaries of control fish 

demonstrated healthy oocyte growth and other normal histological features after 57 days. In contrast, ovaries in 

treated groups exhibited excessive amounts of connective tissue, hyperemia and markedly reduced oocyte number. 

Oocytes had wavy irregular surface outlines. Deviation from normal was observed to be dose dependent. In 

juvenile tilapia, spermatogenesis was observed in control testes. Testes of zinc-exposed fish, on the other hand, 

remained immature. Hyperemia was markedly pronounced in both testes and ovary after 90 days exposure to 

zinc. 
Blood of Tilapia nilotica fingerlings exposed to sublethal concentrations of 2, 5, and 10 ppm zinc for 30, 

60, and 90 days exhibited anisocytosis and poikilocytosis. There was an increase in hematocrit values in 

zinc-reared fish which, however, reverted to control/near control levels at day 90. Hemoglobin values were 

inversely proportional to the level of zinc in the rearing water. The marked reduction in hemoglobin values in 

fish reared at the higher zinc concentrations of 5 and 10 ppm suggests the development of some degree of anemia 

which is also supported by the observations of anisocytosis and poikilocytosis. 

INTRODUCTION 

Heavy metal contamination of aquatic environments has become a current serious 

problem because of increased industrialization. In the Philippines, data gathered by the 

National Environmental Pollution Commission (NEPC 1980) on eleven river systems 
and of researches monitoring levels of heavy metals in fishes indicate high 

concentrations of these substances in aquatic bodies (NEPC 1980; PCARRD 1982). 

Compared to seas and oceans, fresh water environments are more vulnerable to pollution 

stress inasmuch as they are smaller systems and have more limited numbers and kinds of 

organisms. Pollution of lakes and rivers, thus, pose alarming dangers to aquatic life, as 

for example to fish. 

One fresh water fish which is presently being studied intensively insofar as its 

response to heavy metals contamination, is Tilapia nilotica L. Economically 

33 



BIOTROPIA No. 6, 1992/1993 

important as a poor man's protein source, it is easily available and is a hardy fish species. 

Thus, it is expected that less sturdy fishes would exhibit any effect manifested by this 

particular species. Most of the studies that will be reported in this paper deal with the 

effects of zinc on posthatch larvae or fry of Tilapia nilotica. This stage of development, is a 

good investigative material since a number of organs, e.g., the gonads have not 

completed full development and differentiation. The earlier developmental stages are 

interesting subjects, but in T. nilotica they are not too exposed to the environment 

inasmuch as they brood in the tilapia mother's mouth and are hence semi-protected. 

MATERIALS AND METHODS 

Preliminary 96 hr LD
50

 determination was performed to obtain the approximate 

sublethal levels of zinc on the T. nilotica stage that would be tested. During the four 

days period the fish were kept in aerated water with different concentrations of ZnSO4 

and were starved to minimize the elimination of the metal together with waste products. 

Dechlorinated tap water was used in all tests. Hardness, alkalinity, and pH 

readings were taken twice a week on the test water in the aquarium. Hardness and 

alkalinity were determined by titration method (APHA 1971). Temperature was 

monitored daily. 

Zinc sulphate (ZnSO4. 7H2O, AR Merck
®
 ) was dissolved in deionized water and 

acidified to pH 2 with nitric acid (HNO3). The plastic jars with 3.0 1 test water were 

spiked with zinc solution to bring the concentration to the desired level. 

Posthatch fry of T. nilotica were obtained from a single source and acclimated in well 

aerated dechlorinated tap water for 7 days prior to experimentation. Chronic as well as acute 

exposures to zinc were done at different time exposures. The organs to be reported on are 

the gills, gonads, and blood. 

For light microscopy, tissues were dehydrated in a series of graded ethyl alcohol, 

cleared in cedarwood oil and xylene, infiltrated and embedded in paraffin, and cut in AO
®
 

rotary microtome. Paraffin sections of 7 urn thickness were stained with 

Hematoxylin-Eosin and mounted in Entellan
®
 mounting medium. 

Resin sections were also done. Tissues dissected were fixed in 2.5% 

glutaraldehyde in phosphate buffer, pH 7.2, followed by post-fixation in 1% osmium 

tetroxide. The samples were dehydrated in ethanol and propylene oxide, embedded in 

Araldite
®
 , sectioned 1 - 2 urn thick with Carl Zeiss

®
 ultratome, stained with 1 % toluidine 

blue and examined under the light microscope. Ultrathin sections were stained with uranyl 

acetate and lead citrate for electron microscopy. 

34 



Effects of the heavy metal, zinc, on Tilapia nilotica L. - V.S. Cariffo 

For blood parameters, fingerlings were reared in zinc concentrations of 2, 5, and 10 

ppm for 30, 60, and 90 days (Cariño and Casauay 1991). Blood samples were collected 

by gill puncture using heparinized capillary tubes and analyzed for haematocrit and 

haemoglobin content using capillary method (Hesser 1960) and ALS Biochemical 

Haemoglobin Procedure
®
 , USA, respectively. Blood smears were made and stained with 

Giemsa for erythrocyte morphology. 

RESULTS AND DISCUSSION 

Effects on Gills 

In tilapia fingerlings exposed to 10 ppm and 20 ppm zinc sulfate for 21 days, the 

main effect was hyperplasia of the primary gill epithelia resulting in fusion of adjacent 

secondary lamellae (Cariño & Puzon 1986). Hyperplasia was noted in all treatment groups, 

both short-term exposure (4 hours) to 30 ppm lethal concentration of zinc and long-term 

treatment (21 days) to 20 ppm chronic and 10 ppm sublethal levels of the metal (Figs. 1 & 

2). Extensive cell proliferation was noted along the entire length of the gill filaments of 

fish exposed to the highest zinc concentration 

 

Figure 1.  Longitudinal section of control gill filament. CC, chloride cell; SEC, secondary epithelial cell; SL, 

secondary lamellae; PC, pillar cell; BC, blood cell; GL, gill ray. X960. 

35 



 

Figure 2.  Longitudinal section of gill filament from 10-ppm exposed fish showing fusion of adjacent 

secondary gill lamellae. CC, chloride cell; OR, gill ray. X480. 

used, 30 ppm. The overall effect of the zinc salt on the gill structure is the decrease in 

surface area which would otherwise make for an efficient transport of oxygen in the 

blood. 

Other investigations showed that chemically induced hyperplasia of the primary gill 

epithelia is generally due to the increase in the number of chloride cells (Ahuja 1970; 

Crespo 1981; Tuurala & Soivio 1982; Crespo 1984). Zinc was particularly shown to 

induce proliferation of the chloride cells in the dogfish Synliorhinus canicula (Crespo 

1981). Increase in chloride cells have likewise been noted in the study of Cariño & Puzon 

(1986) with T. nilotica fingerlings. This indicates to invigorate osmoregulatory 

capacities. 

Chloride cells are large salt secretory cells (Karnaky et al. 1977) found at the base of 

the secondary gill filament and believed to be responsible for osmoregulation (Karnaky 1980; 

Laurent & Dunel 1980). They have been shown to excrete univalent ions, though they might 

also be able to excrete bivalent ions (Ahuja 1970). Na-K-ATPase is the major enzyme 

found in chloride cells. 

Thickening or hypertrophy of the secondary gill epithelia was a less observable effect of 

zinc exposure in T. nilotica fingerlings. This was observed with 20 ppm treatment (Figs. 

3 & 4). 

36 

BIOTROPIA No. 6, 1992/1993 



Effects of the heavy metal, zinc, on Tilapia nilotica L. - V.S. Carino 

 

Figure 3.  Longitudinal section of gill filament from 20-ppm exposed fish showing fusion (F) of secondary gill 

lamellae and hypertropy (arrow) of secondary epithelial cell. CC, chloride cell; SEC, secondary 

epithelial cell; GR, gill ray. X480. 

 

Figure 4.  Longitudinal section of gill filament from 20-ppm exposed fish showing hyperplasia of chloride cell 

and fusion of secondary gill lamellae. CC, chloride cell; PC, pillar cell; BC, blood cell; GR, gill ray. 

X960. 

37 



BIOTROPIA No. 6, 1992/1993 

Hypertrophy of secondary gill epithelia has been reported as a response of fish to 

industrial pollutants. Hughes et al. (1979) noted that there was increase in the volume of 

secondary epithelia in nickel exposed Salmo gairdneri. Chromium has similar effect on 

the secondary epithelia of this species (Putte et al. 1981). Tuurala and Soivio (1982) 

observed that excessive hypertrophy of the secondary epithelial cells was induced by 

sublethal exposure of S. gairdneri to dihydroabietic acid, a major kraft pulping effluent 

(Leach & Thakore 1973). Similar results have been obtained with exposure of Chanos 

chanos fingerlings to ammonia (Cruz & Enriquez 1982). 

Secondary lamellar hypertrophy increases the diffusing distance from the 

surrounding water to capillaries, but decreases the respiratory dead volume between the 

secondary lamellae and, thus, would compensate for the increase in the diffusion distance 

(Tuurala & Soivio 1982). 

Histological observations indicate that zinc impairs gaseous exchange in fishes by 

increasing diffusion distance and decreasing absorption surface area. 

Electron microscopic structure of the secondary lamella of control fish is shown in Fig. 5. 

The lamellar blood sinus is large and circular in outline. The pillar cell and its nucleus is 

very distinct. Fish exposed to 2 ppm zinc for 21 days were observed to have lamellar blood 

sinus dilation and epithelial lifting of the secondary gill lamella (Fig. 6). Detachment of 

pillar cell from the epithelium occurred at 20 ppm zinc exposure. Epithelial lifting 

results in the enlargement of the non-tissue spaces. 

 

38 

Figure 5. Electron micrograph of control secondary gill lamellae. X5000. 



Figure 6.  Electron micrograph of gill lamellae from 2-ppm exposed fish showing dilated blood sinus 
epithelial lifting. X5000. 

Effect on the Gonads 

Gonads of 30-day posthatch control fry exhibited gonial multiplication (Cariño 

& Cruz 1990). No distinction can yet be made as to whether the gonad is testis or ovary. 

In contrast, all experimental fish reared for 30 days in three zinc concentrations had 

gonads that contained only primordial germ cells. Gonial multiplication was delayed. 

In fish harvested after 57 days in culture, oocyte growth is observed in both control and 

zinc-treated fish (Figs. 7a, b). A notable difference is the presence of promiscuous and 

dilated blood vessels densely filled with blood cells in the ovaries of zinc-treated fish. 

Oocytes of zinc-treated fish have more nucleoli than control fish. A number of these 

nucleoli-studded nuclei bear on one side a quarter moon-shaped region of intensely 

darkly stained material which is most probably extruded RNA. Accumulation of 

maternal RNA is characteristic of most growing oocytes. Graded distinctions between 

ovaries treated with 2, 5, and 10 ppm appear inconspicuous. Tests of 57-day reared control 

and zinc-treated fish showed spermatogonial multiplication. As noted by Casauay & 

Carifio (1988), spermatogenesis in Tilapia nilotica commences later than oogenesis. 

Testes of juvenile T. nilotica showed spermatogenic stages. In contrast, zinc-treated 

fish showed delay in spermatogenesis (Figs. 8a, b). 

39 

Effects of the heavy metal, zinc, on Tilapia nilotica L. - V.S. Carino 



BIOTROPIA No. 6, 1992/1993 

Figure 7.  Oocyte growth from 57-day cultured fish (a) Control ovary, (b) Zinc treated fish ovary showing 

abundant blood cells. X5000. 

40 



Effects of the heavy metal, zinc, on Tilapia nilotica L. - V.S. Cariffo 

 

Figure 8.  Spermatogenic stages in control juvenile T. nilotica; b. Delay in spermatogenesis in zinc treated fish. 
X400. 

41 



 

Figure 9.  Blood smear from a contol Tilapia nilotica; b. Blood smear showing "anisocyclosis", a term applied 

when the RBCs vary in size (arrow) after exposure to 2, 5, and 10 ppm zinc concentration, c. 

"Poikilocytosis" exhibited by abnormal variation in shape of RBC after 2, 5, and 10 ppm exposure to 

zinc. XI000. 

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BIOTROPIA No. 6, 1992/1993 



Effects of the heavy metal, zinc, on Tilapia nilotica L. - V.S. Carino 

Effects on the Blood 

Anisocytosis and poikilocytosis were noted in the blood smears of zinc-treated fish (9a, 

b, c). In all zinc treated fish, an increase in hematocrit (%) was observed at 30 days. With 

the exception of fish reared at 10 ppm zinc, hematocrit values dropped to control/near 

control levels after 90 days. Haemoglobin (g/1) content in fish reared in zinc-treated 

water for 90 days was inversely related to zinc concentration. Exposure of Tilapia 

nilotica fingerlings for 90 days to zinc concentrations of 5 and 10 ppm induced anemia 

reducing haemoglobin content of erythrocytes and not by reduced number of 

erythrocytes. 

REFERENCES 

AHUJA S.K. 1970. Chloride cell and mucus-cell responses to chloride and sulphate enriched media in the gills of 

Gambusia affinis (Baird and Girard) and Cat/a catla (Hamilton). J. Exp. Zool. 173: 231-250.  

American Public Health Association, American Water Works Association, and Water Pollution Control 
Federation 1971. Standard Methods for the Examination of Water and Wastewater. 13th ed., 
American Public Health Association, NY, USA.  

CARIÑO, VIRGINIA S. and ARMANDO G. PUZON, Jr. 1986. Toxic effects of zinc sulphate to Tilapia nilotica L. fingerlings. 

Natural and Applied Science Bulletin 38(2):127- 134.  

CARIÑO, VIRGINIA S. and ARSENIA A. CASAUAY. 1991. The haemocytology of Tilapia nilotica and blood studies on Tilapia 
nilotica fingerlings after sublethal exposure to zinc. Science Diliman 25(1):6 - 22.  

CARIÑO, V.S. and N.C. CRUZ. 1990. Effects of low levels of zinc on the ovarian development of Tilapia nilotica L. 

Sci. Diliman 3:34-45 

CASAUAY, A.A. and CARINO, V.S. 1988. Gonadal sex differentiation in Oerochromis niloticus. In: R.S.V. Pullin, 
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in Aquaculture. ICLARM Conference Proceedings, Department of Fisheries, Bangkok, Thailand and 
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CRESPO, S. 1982. Surface morphology of dogfish (Scyliorhinus canicula) gill epithelium, and surface 

morphological following treatment with zinc sulphate: As canning electron microscope study. Mar. Biol. 

67:159-166. 

CRESPO, S. 1984. An in vitro study of the effects of zinc on the osmoregulatory processes. Mar. Pollut. Bull. 

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CRUZ, E.R. and G.L. ENRIQUEZ. 1982. Gill lesions associated with acute exposure to ammonia. Nat. Appl. Sci. 

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HESSER, E.F. 1960. Methods for routine fish hematology. Prog. Fish Cult. 22(4):164- 171.  

HUGHES, G.M., S.G. PERRY, and V.M. BROWN. 1979. A morphometric study of effects of nickel, chromium, and 

cadmium on the secondary lamellae of rainbow trout gills. Water Res. 13:665 - 679. 

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KARNAKY Jr. K.J., J. KARL, Jr., and W.B. KINTER. 1977. Killifish opercular skin. A flat epithelium with a high 
density of chloride cells. J. Exp. Zool. 199:355-364. 

 LEACH, J.M. and A.N. THAKORE. 1973. Identification of the constituents of kraft pulping effluent that are toxic to 
juvenile coho salmon (Onchorynchus kisutch). J. Fish Res. Board Can. 30:479-484. 

NATIONAL ENVIRONMENTAL  PROTECTION  COUNCIL.   1980.  The  Philippine Environment.  Manila: 52-56.  

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BRINKHORST, and J.H. KOEMAN. 1981. Effecf-of pH on the acute toxicity of hexavalent chromium to rainbow trout 
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