Only Part of the Protein in Feed is Available to the Fish This Part is Called What

2. ESSENTIAL NUTRIENTS - PROTEINS AND AMINO ACIDS

2.1 Proteins

The proteins are among the most important constituents of all living cells and represent the largest chemical group in the animal body, with the exception of water; the whole fish carcass contains on average 75% water, 16% protein, 6% lipid, and 3% ash. Proteins are essential components of both the cell nucleus and cell protoplasm, and accordingly account for the bulk of the muscle tissues, internal organs, brain, nerves and skin.

2.1.1 Composition

Proteins are very complex organic compounds of high molecular weight. In common with carbohydrates and lipids, they contain carbon (C), hydrogen (H), and oxygen (O), but in addition also contain about 16 % nitrogen (N: range 12–19%), and sometimes phosphorus (P) and sulphur (S).

2.1.2 Structure

Proteins differ from other biologically important macromolecules such as carbohydrates and lipids in their basic structure. For example, in contrast to the basic structure of carbohydrates and lipids, which is often composed of identical or very similar repeating units (ie. the glucose repeating unit within starch, glycogen and cellulose), proteins may have up to 100 different basic units (amino acids). It follows therefore that greater compound variabilities and ranges are possible, not only to composition, but also to protein shape.

2.1.3 Chemical properties

Colloidal in nature, proteins vary in their solubility in water, from insoluble keratin to the highly soluble albumins. All proteins can be 'denatured' by heat, strong acid, alkali, alcohol, acetone, urea and by heavy metal salts. When proteins are denatured they loose their unique structure, and therefore possess different chemical, physical and biological properties (ie. inactivation of enzymes by heat).

2.1.4 Classification

Proteins maŷ be classified into three main groups according to their shape, solubility and chemical composition:

Fibrous proteins: insoluble animal proteins which are generally very resistant to digestive enzyme breakdown. Fibrous proteins exist as elongated filamentous chains. Examples of fibrous proteins include the collagens (main protein of connective tissue), elastin (present in elastic tissues such as arteries and tendons), and keratin (present in hair, nails, wool and hooves of mammals).
Globular proteins: include all enzymes, antigens and hormone proteins. Globular proteins can be further subdivided into albumins (water soluble, heat-coagulable proteins which occur in eggs, milk, blood and many plants); globulins (insoluble or sparingly soluble in water, and present in eggs, milk, and blood, and serve as the main protein reserve in plant seeds); and histones (basic proteins of low molecular weight, water soluble, occur in the cell nucleus associated with deoxyribonucleic acid - DNA).
Conjugated proteins: these are proteins which yield non-protein groups as well as amino acids on hydrolysis. Examples include the phosphoproteins (casein of milk, phosvitin of egg yolk), glycoproteins (mucous secretions), lipoproteins (cell membranes), chromoproteins (haemoglobin, haemocyanin, cytochrome, flavoproteins), and nucleoproteins (combination of proteins with nucleic acids present in the cell nucleus).

2.2 Protein function

The function of proteins may be summarised as follows:

To repair worn or wasted tissue (tissue repair and maintenance) and to rebuild new tissue (as new protein and growth).
Dietary protein may be catabolized as a source of energy, or may serve as a substrate for the formation of tissue carbohydrates or lipids.
Dietary protein is required within the animal body for the formation of hormones, enzymes and a wide variety of other biologically important substances such as antibodies and haemoglobin.

2.3 Protein requirements

The study of dietary nutrient requirements in fishes and shrimp has been almost entirely based on studies comparable to those conducted with terrestrial farm animals. It follows therefore that almost all the available information on the dietary nutrient requirements of aquaculture species is derived from laboratory based feeding trials; the animals being kept in a controlled environment at high density and having no access to natural food organisms.

2.3.1 Optimum dietary protein level

Based on feeding techniques pioneered and developed for terrestrial animals the dietary protein requirements of fish were first investigated in the Chinnok salmon (Oncorhynchus tshawytscha) by Delong, et al, (1958). Fish were fed a balanced diet containing graded levels of a high quality protein (casein:gelatin mixture supplemented with crystalline amino acids to simulate the amino acid profile of whole hen's egg protein) over a 10-week period and the observed protein level giving optimum growth was taken as the requirement (Fig. 2). Since these early studies the approach used by workers today has changed very little if at all, with the possible exception of the use by some researchers of maximum tissue protein retention or nitrogen balance in preference to weight gain as the criterion of requirement (Ogino, 1980). Dietary protein requirements are normally expressed in terms of a fixed dietary percentage or as a ratio of protein to dietary energy.

Fig. 2. Typical dose response curve

To date over 30 fish and shrimp species have been examined in this manner and the results show a uniformly high dietary protein requirement in the range 24–57%, or equivalent to 30–70% of the gross energy content of the diet in the form of protein (Table 1). Whilst a high protein requirement might have been expected for carnivorous fish species, such as plaice (Pleuronectes platessa-50%; Cowey et al, 1972) or snakehead (Channa micropeltes-52%; Wee and Tacon, 1982), the fact that a relatively high protein requirement was also observed in the herbivorous grass carp (Ctenopharyngodon idella 41–43%; Dabrowski, 1977) suggests that the requirement may in part be a function of the methodology used for its determination. The use by different workers of different dietary protein sources, non-protein energy substitutes, feeding regimes, fish age classes and methods for the determination of dietary energy content and dietary requirement leaves little common ground for direct comparisons to be made within or between fish speceis. For example, the high protein requirement observed for grass carp fry (41–43%; Dabrowski, 1977) almost certainly arose from all experimental fish being fed a restricted ration (fish fed only twice daily, and fixed on the lowest recorded ad libitum feed take) and consequently fish fed the lower protein diets not being able to consume sufficient feed to meet their dietary protein and energy requirements. A critical review of the methods used for the estimation of dietary protein and amino acid requirements in fish and crustacea has been made by Tacon and Cowey (1985) and Cowey and Tacon (1983) respectively.

The high dietary protein requirement of fish and shrimp is generally attributed to their carnivorous/omnivorous feeding habit, and their preferential use of protein over carbohydrates as a dietary energy source (Cowey, 1975). In contrast to terrestrial farm animals fish and shrimp are able to derive more metabolizable energy from the catabolism of proteins than from carbohydrates.

2.3.3 Abiotic factors - temperature and salinity

The influence of water temperature on protein requirement and fish growth has been the subject of numerous investigations. The early study of DeLong and co-workers with fingerling Chinook salmon (O. tshawytscha) was said to show an increase in the dietary protein requirement from 40% to 55% with an increase in water temperature from 8.3°C to 14.4°C (DeLong, et al., 1958). More recently, a similar rise in dietary protein requirement was reported in fingerling Striped bass (Morone saxatilis) from 47% to 55% with an increase in water temperature from 20.5°C to 24.5°C (Millikin, 1983; Table 1). In contrast, fingerling rainbow trout (Salmo gairdneri) showed no difference in growth at dietary protein levels of 35%, 40% and 45% at temperatures of 9°C, 12°C, 15°C and 18°C in one study (Slinger et al., 1977) or in another study with temperatures of 9°C, 15°C and 18°C (Cho and Slinger, 1978). Although distinct temperature effects were observed in terms of growth, the greater absolute need for protein at the higher water temperatures was apparently satisfied through the increased consumption of the lower protein diets. These latter studies are in line with the hypothesis that an increase in water temperature (up to an optimum level) is accompanied by an increased feed intake (Brett, et al., 1969; Choubert, et al., 1982), increased growth rate and metabolic rate (Jobling, 1983) and a faster gastro-intestinal transit time (Fauconneau, et al., 1983; Ross and Jauncey, 1981) under conditions where food supply is not limiting. The weight of evidence is that increased water temperature does not lead to an increased protein requirement. In both cases where such a requirement was claimed, the effect of water temperature on dietary protein requirement was investigated by comparing the results obtained in successive experiments at different water temperatures. In addition, the sub-optimal growth and increased feed intake observed with fish fed the higher protein diets suggests that the ad libitum feeding regime employed in fact led to a restricted feed intake.

TABLE 1. Dietary protein requirement of fish and shrimp (expressed as % of dry diet)
Species	Dietary protein requirement	Size range ¹	Feeding regime ²	Culture system	Reference
FISH
Oreochromis mossambicus	40	Fingerling	6%bw/d	Indoor/tank	Jauncey (1982)
Oreochromis niloticus	35	Fry	15%bw/d	Indoor/tank	Santiago et al., (1982)
O. niloticus	28–30	Fry/fing.	6%bw/d	Indoor/tank	De Silva & Perera (1985)
O. niloticus	25	Fingerling	3.5%bw/d	Indoor/tank	Wang, Takeuchi & Watanabe (1985)
O. niloticus	35	Fingerling	4%bw/d	Indoor/tank	Teshima, Kanazawa & Uchiyama (1985)
O. niloticus	19–29	Juvenile	3%bw/d	Outdoor/cage	Wannigama, Weerakoon & Muthukumarama (1985) ^a
O. niloticus/aureus hybrids	30	Grower	2–2.5%bw/d	Outdoor/pond	Viola & Zohar (1984) ^b
Oreochromis aureus	30	Fingerling	6%bw/d	Indoor/tank	Toledo, Cisneros & Ortiz (1983)
O. aureus	36	Fingerling	8.8%bw/d	Indoor/tank	Davis & Stickney (1978)
O. aureus	56	Fry	20%bw/d	Indoor/tank	Winfree & Stickney (1981)
O. aureus	34	Fingerling	10%bw/d	Indoor/tank	Winfree & Stickney (1981)
Tilapia zilli	35	Fingerling	5%bw/d	Indoor/tank	Mazid et al., (1979)
T. zilli	35–40	Fingerling	4%bw/d	Indoor/tank	Teshima, Gonzalez & Kanazawa (1978)
Cyprinus carpio	35	Grower	5%bw/d	Indoor/tank	Jauncey (1981)
C. carpio	34	Fingerling	Ad.lib.	Indoor/tank	Murai et al., (1985)
C. carpio	38	Fingerling	Ad.lib.	Indoor/tank	Ogino & Saito (1970)
Ctenopharyngodon idella	41–43	Fry	Fixed (?)	Indoor/tank	Dabrowski (1977)
Mugil capito	24	Fingerling	Ad.lib.	Indoor/tank	Papaparaskeva-Papoutsoglou & Alexis (1985)
Ictalurus punctatus	35	Grower	Fixed (1–4%bw/d)	Outdoor/cage	Lovell (1972) ^c
I. punctatus	29–42	Grower	Fixed (1–4%bw/d)	Outdoor/pond	Prather & Lovell (1973) ^d
I. punctatus	45	Grower	Fixed (34–45kg/ha/d)	Outdoor/pond	Lovell (1975) ^e
I. punctatus	25	Grower	Ad.lib.	Indoor/tank	Page & Andrews (1973)
I. punctatus	36	Fingerling	3%bw/d	Indoor/tank	Garling & Wilson (1976)
I. punctatus	25	Juvenile	Fixed (3–4%bw/d)	Outdoor/pond	Deyoe et al., (1968) ^f
I. punctatus	35	Juvenile/grow.	3%bw/d	Indoor/tank	Page & Andrews (1973)
Alosa sapidissima	42.5	Fingerling	Ad.lib.	Outdoor/tank	Murai, Fleetwood & Andrews (1979)
Pangasius sutchi	25	Fry/fing.	10%bw/d	Indoor/tank	Chuapoehuk & Pthisoong (1985)
Chanos chanos	40	Fry	10%bw/d	Indoor/tank	Lim et al., (1979)
Channa micropeltes	52	Grower	2%bw/d	Indoor/tank	Wee & Tacon (1982)
Fugu rubripes	50	Fingerling	10%bw/d	Indoor/tank	Kanazawa et al, (1980)
Chrysophrys aurata	38.4	Fingerling/juv.	Ad.lib.	Indoor/tank	Sabaut & Luquet (1973)
Morone saxatilis	47	Fingerling	Ad.lib.	Indoor/tank	Millikin (1983)
M. saxatilis	55	Fingerling	Ad.lib.	Indoor/tank	Millikin (1982) ^g
Anguilla japonica	44.5	Fingerling	Ad.lib.	Indoor/tank	Nose & Arai (1973)
Micropterus dolomieui	45.2	Fry/fing.	Ad.lib.	Indoor/tank	Anderson et al., (1981)
Micropterus salmoides	40–41	Fingerling	Ad.lib.	Indoor/tank	Anderson et al., (1981)
Pleuronectes platessa	50	Juvenile	Ad.lib.	Indoor/tank	Cowey et al., (1972)
Salvelinus alpinus	36–43.6	Juvenile/grow.	Ad.lib.	Indoor/tank	Jobling & Wandsvik (1983)
Salmo gairdneri	42	Grower	Fixed (?)	Indoor/tank	Austreng & Refstie (1979)
S. gairdneri	40	Fingerling/juv.	Fixed	Indoor/tank	Satia (1974) ^h
S. gairdneri	40–45	Fingerling/juv.	Ad.lib.	Indoor/tank	Zeitoun et al., (1973) ⁱ
PRAWN
Macrobrachium rosenbergii	40	PL 0.15g	12-5%bw/d	Indoor/tank	Millikin et al., (1980)
M. rosenbergii	15	PL 0.12g	Fixed	Outdoor/tank	Boonyaratpalin & New (1982) ^j
M. rosenbergii	35	PL 0.10g	5%bw/d	Outdoor/tank	Balazs & Ross (1976) ^k
M. rosenbergii	27	PL 1.90g	5%bw/d	Outdoor/pond	Stanley & Moore (1983) ^l
SHRIMP
Penaeus indicus	30–40	PL 1–42 day	Fixed	Indoor/tank	Bhaskar & Ali (1984) ^m
P. indicus	43	PL 0.4–1.1g	10–15%bw/d	Indoor/tank	Colvin (1976)
Penaeus aztecus	≤40	PL 24–135mg	100-50%bw/d	Indoor/tank	Venkataramiah, Lakshmi & Gunter (1975)
P. aztecus	43–51	PL 0.4–1.3g	Fixed (?)	Indoor/tank	Zein-Eldin & Corliss (1976) ⁿ
Penaeus setiferus	28–32	Juveniles 4g	5%bw/d	Indoor/tank	Andrews, Sick & Baptist (1972)
Penaeus merguiensis	50–55	Juv. 3–8g	Fixed (?)	Indoor/tank	AQUACOP (1978) ⁿ
P. merguiensis	34–42	PL 0.3g	Fixed (?)	Indoor/tank	Sedgwick (1979) ⁿ
Penaeus monodon	55	PL 2mg	Fixed (?)	Outdoor/tank	Bages & Sloane (1981) ^o
P. monodon	34	PL 5mg	100%bw/d	Indoor/tank	Khannapa (1977)
P. monodon	40	PL 25mg-0.7g	100-10%bw/d	Indoor/tank	Khannapa (1977)
P. monodon	40	Juv. 1–3g	Fixed (?)	Indoor/tank	AQUACOP (1977) ⁿ
P. monodon	45.8	PL 0.5–1g	Fixed (?)	Indoor/tank	Lee (1971) ⁿ
Penaeus vannamei	≥36	Juv. 4–20g	Fixed (?)	Indoor/tank	Smith et al., (1985) ⁿ
P. vannamei	30–35	PL 32mg-0.5g	(?)	Indoor/tank	Colvin & Brand (1977)
Penaeus stylirostris	30–35	PL 45mg	(?)	Indoor/tank	Colvin & Brand (1977)
P. stylirostris	44	PL 5mg	(?)	Indoor/tank	Colvin & Brand (1977)
Penaeus californiensis	44	PL 5mg	(?)	Indoor/tank	Colvin & Brand (1977)
P. californiensis	≤30	Juv. 1g+	(?)	Indoor/tank	Colvin & Brand (1977)
Penaeus japonicus	52–57	PL 0.8g	Ad.lib.	Indoor/tank	Deshimaru & Yone (1978)
P. japonicus	>40	Juv. 1–2g	Fixed (?)	Indoor/tank	Balazs, Ross & Brooks (1973) ⁿ
P. japonicus	54	PL 0.6–1g	Ad.lib.	Indoor/tank	Deshimaru & Kuroki (1974)
Palaemon serratus	30–40	PL 0.1–0.2g	Fixed (?)	Indoor/tank	Forster & Beard (1973) ⁿ

¹ Fish size range: fry 0–0.5g, fingerling 0.5–10g, juvenile 10–50g, grower 50g and above.
² Feeding regime: %bw/d - fixed feed intake expressed as a percentage of body weight per day, or Ad libitum feeding two to four times daily.
^a No difference in protein requirement at three stocking densities of 400, 600 and 800 fish/m³, using 5m³ cages.
^b 200m² earthen ponds, fish density of 2/m², ponds also fertilized with poultry litter at a rate of 5kg/pond/week.
^c Fish stocking density of 300/m³.
^d/^e Fish stocking density of 9880/hectare.
^f Plastic lined ponds, with fish stocking density of 3000–3700/hectare.
^g Increased dietary protein requirement reported for fingerling striped bass from 47 to 55% with an increase in water temperature from 20.5 to 24.5°C.
^h Feed intake fixed within all groups to the lowest recorded Ad libitum feed intake observed.
ⁱ Protein requirement said to increase from 40 to 45% with increasing salinity.
^j Outdoor concrete ponds, 5 animals/m², infrequent water exchange, all animals fed at same fixed rate based on highest recorded intake.
^k outddor fibreglass tanks, 17 animals/m², high water exchange.
^l Animals housed within pens in earthen pond, 10 animals/m².
^m All animals fed at fixed rate of 5mg feed/larvae/day (PL 1–10), 15mg feed/larvae/day (PL 11–50), and 20mg feed/larvae/day (PL 24–42).
ⁿ All animals fed to excess once or twice daily.
^o Diet formulated to 55% crude protein, but actual level after diet processing was 45%.

Very few studies have been undertaken concerning the effect of salinity on protein requirement. Experiments conducted with fingerling rainbow trout ( a euryhaline fish) are reported to show an increase in the absolute dietary requirement for protein from 40% to 45% with a salinity increase from 10 to 20 parts per thousand (Zeitoun, et al., 1973; Table 1). However, no increase in dietary protein requirement was observed in a similar experiment conducted with Coho salmon fingerlings (O. kisutch); Zeitoun et al., 1974). In view of the speculative method for arriving at dietary requirement from the dose response curve (Zeitoun et al., 1973), and the lack of information on the protein requirements of these fish species in full strength sea water (35 parts per thousand), there are no firm data demonstrating that the protein requirements of fish are elevated with increased salinity. There is no information on the effect of salinity on the protein requirement of shrimp.

2.4 Amino acids

Although over 100 different amino acids have been isolated from biological materials, only 25 of these are commonly found in proteins. Individual amino acids are characterised by having an acidic carboxy group (-COOH) and a basic nitrogenous group (generally an amino group: -NH₂). In view of the presence of both acidic and basic groups, amino acids are amphoteric (ie. have both acidic and basic properties) and consequently act as buffers by resisting changes in pH. The chemical structure of the more commonly occurring amino acids is shown below:

2.5 Amino acid function

Amino acids occupy a central position in cellular metabolism since almost all biochemical reactions are catalysed by enzymes composed of amino acid residues. Amino acids are essential for carbohydrate and lipid metabolism, for the synthesis of tissue proteins and many important compounds (ie. adrenalin, thyroxine, melanin, histamine, porphyrins - haemoglobin, pyrimidines and purines - nucleic acids, choline, folic acid and nicotinic acid - vitamins, taurine - bile salts etc), and as a metabolic source of energy or fuel.

2.6 Amino acid requirements

For nutritional purposes, amino acids may be divided into two groups; the essential amino acids (EAA), and the non-essential amino acids (NEAA). EAA are those amino acids that cannot be synthesized within the animal body or at a rate sufficient to meet the physiological needs of the growing animal, and must therefore be supplied in a ready made form in the diet. NEAA are those amino acids that can be synthesized in the body from a suitable carbon source and amino groups from other amino acids or simple compounds such as diammonium citrate, and consequently do not have to be supplied in a ready made form in the diet.

The dietary EAA for fish and shrimp are as follows:


Threonine	Valine
Leucine	Isoleucine
Methionine	Tryptophan
Lysine	Histidine
Arginine	Phenylalanine

Although the NEAA are not dietary essential nutrients, they perform many essential functions at the cellular or metabolic level. They are termed dietary non-essential nutrients only because the body tissues can synthesize them on demand. In fact it is often quoted that the NEAA are physiologically so essential that the body ensures an adequate supply by synthesis. From a feed formulation viewpoint, it is important to know that the NEAA's cystine and tyrosine can be synthesized within the body from the EAA's methionine and phenylalanine respectively, and consequently the dietary requirement for these EAA is dependent on the concentration of the corresponding NEAA within the diet.

2.6.1 Optimum dietary essential amino acid levels

(a) Dose response and carcass deposition method: The quantitative EAA requirements of fish have traditionally been determined by feeding graded levels of each amino acid within an amino acid test diet so as to elicit a dose response curve (for review see Ketola, 1982; Cowey and Luquet, 1983; Wilson, 1985). Dietary requirement is then usually taken at 'break point' on the basis of the observed growth response. In addition to growth, several workers have also used free amino acid levels within specific tissue pools (whole blood, blood plasma or muscle; Kaushik, 1979), or the oxidation of radioactively labelled amino acids (administered orally or by injection; Walton, Cowey and Adron, 1982) as the criterion for estimating dietary requirement. Within the amino acid test diets used the protein component is supplied almost entirely in the form of crystalline amino acids or in combination with selected 'whole' protein sources (commonly either casein, gelatin, zein, gluten or fish meal); the amino acid profile of the total protein component of the diet being controlled so as to simulate the amino acid profile of a specific reference protein.

In contrast to the above standard method where fish are fed graded levels of crystalline amino acids, Ogino (1980a) determined the quantitative EAA requirement of fish simultaneously on the basis of the daily deposition of individual amino acids within the fish carcass. In the Ogino method fish are fed a diet containing a 'whole' protein source of high biological value, and the dietary EAA requirement computed on the basis of the observed daily EAA tissue deposition value.

Table 2 summarises the known quantitative EAA requirements of fish studied to date using the above mentioned techniques. Quantitative dietary requirements for all 10 EAAs have been established for only five fish species (common carp C. carpio, rainbow trout S. gairdneri, channel catfish I. punĎtatus, Japanese eel A. anguilla, and the Chinook salmon O. tshawytscha). At present there is no quantitative information on the dietary EAA requirements of shrimp; in the main this has been due to the poor growth observed with shrimp fed synthetic amino acid test diets and the inherent problems of nutrient leaching due to the extended feeding habits of shrimp.

Although numerous independent studies have recently been performed on the amino acid requirements of rainbow trout, significant differences in requirement (g amino acid/100g protein) exist within and between individual fish species (Table 2). For example, differences of the order of 65%, 72% and 114% were observed between independent laboratories for the lysine, arginine and methionine requirement of fingerling/juvenile rainbow trout. Similarly, inter-species variations ranged from 22% for valine to as high as 122% for tryptophan. Whilst one would have expected the quantitative EAA requirements of fish to decrease with age and decreasing protein synthesis (growth), one may well question whether or not the observed variations in requirement are real or merely an artifact of the method employed. In contrast to the variations in requirement observed for the same fish species fed conventional amino acid test diets, there was no significant difference in the EAA requirement of carp and trout on the basis of the carcass deposition method of Ogino (1980a). However, the dietary requirements observed are within the range reported for fish fed amino acid test diets (Table 2).

Compared with the conventional method of feeding graded levels of individual amino acids, the carcass deposition method of Ogino (1980a) offers numerous advantages:

Fish are fed rations in which the protein component is supplied in the form of a 'whole' protein of high biological value. Amino acid requirements can therefore be ascertained in fish displaying optimal growth.
The dietary requirement for all ten EAAs can be determined simultaneously in one single experiment. Using conventional amino acid test diets up to 10 separate experiments have to be performed, each experiment involving the use of up to six dietary regimes employing varying dietary concentrations of the single EAA under test.
Quantitative EAA requirements can equally be established for first feeding fry and brood-stock fish with no loss of precision.

Table 2. Quantitative essential amino acid (EAA) requirements of selected fish species. Values are expressed in order as a percentage of the dietary protein and as a percentage of the dry diet (the denominator being the percentage protein in the diet)
Species	Simulated amino acid (AA) profile of protein source	Feeding regime ¹	Initial body weight (g)	Arginine
Cyprinus carpio	Casein:gelatin (38:12)	Ad.lib. 4f/d	0.5–4.0	3.3(1.3/38.5)
Ictalurus punctatus	Whole hen's egg	3%bw/d, 3f/d	2–10	4.3(1.03/24)
Oncorhynchus tshawytscha	Whole hen's egg	Ad.lib. 3f/d	2–4	6.0(2.4/40)
Oncorhynchus keta	Fish body protein	Ad.lib. 2f/d	1.1	-
O. keta	Fish body protein	Ad.lib. 2f/d	1.1	-
Oncorhynchus kisutch	Whole hen's egg	Ad.lib. 3f/d	2–4	6.0(2.4/40)
Anguilla japonica	?	?	?	3.9(1.7/42)
Salmo gairdneri	Whole hen's egg	?	12–14	>4.0(1.4/35)
S. gairdneri	Whole hen's egg	Fixed (?)	1–2	5.4–5.9(2.5–2.8/47)
S. gairdneri	Fish meal	4.5%bw/d, 3f/d	1.5–9	-
S. gairdneri	Zein:fish meal (1:1)	Ad.lib. 4f/d	20–30	3.43(1.2/35)
S. gairdneri	Casein:gelatin (3:2)	2%bw/d, 3f/d	27	-
S. gairdneri	White cod muscle	2–5%bw/d, 4f/d	5–14	3.5–4.0(1.6–1.8/45)
Dicentrachus labrax	Fish meal composite	1.5%bw/d, 2f/d	35	-
Oreochromis mossambicus	Fish meal composite	4%bw/d, 3f/d	1.7	<4.0(1.59/40)
C. carpio	Calculated on the basis of tissue deposition of EAA, with fish fed a whole protein source of high biological value having a protein digestibility of 80%, and a feeding rate of 3% bw/d for both species (carp 62–74g, 20–25°C; trout 68–127g, 15–18°C)			3.8(1.52/40)
S. gairdneri				3.5(1.4/40)


Species	Histidine	Isoleucine	Leucine	Lysine	Methionine²	Methionine³
C. carpio	2.1(0.8/38.5)	2.5(0.9/38.5)	3.3(1.3/38.5)	5.7(2.2/38.5)	2.1(0.8/38.5) ^a	3.1(1.2/38.5)
I. punctatus	1.54(0.37/24)	2.58(0.62/24)	3.5(0.84/24)	5.1(1.5/30)	1.34(0.32/24) ^b	2.34(0.56/24)
O. tshawytscha	1.8(0.7/40)	2.2(0.9/41)	3.9(1.6/41)	5.0(2.0/40)	1.5(0.6/40) ^c	-
O. keta	1.6(0.7/40)	-	-	4.8(1.9/40)	-	-
O. keta	-	-	-	-	-	-
O. kisutch	1.7(0.7/40)	-	-	-	-	-
A. japonica	1.9(0.8/42)	3.6(1.5/42)	4.8(2.0/42)	4.8(2.0/42)	2.1(0.9/42) ^d	2.9(1.2/42)
S. gairdneri	-	-	-	3.7(1.3/35)	-	-
S. gairdneri	-	-	-	6.1(2.9/47)	-	-
S. gairdneri	-	-	-	-	1.57–2.14(0.55–0.75/35) ^e	-
S. gairdneri	-	-	-	-	-	-
S. gairdneri	-	-	-	-	1.0(0.5/50) ^f	1–2(0.5–1/50)
S. gairdneri	-	-	-	4.3(1.95/45)	-	-
D. labrax	-	-	-	-	2.0(1.0/50) ^h	-
O. mossambicus	-	-	-	4.1(1.62/40)	<1.33(0.53/40) ^g	-
C. carpio	1.4(0.56/40)	2.3(0.92/40)	4.1(1.64/40)	5.3(2.12/40)	1.6(0.64/40)	-
S. gairdneri	1.6(0.64/40)	2.4(0.96/40)	4.4(1.76/40)	5.3(2.12/40)	1.8(0.72/40)	-

Species	Phenylalanine⁴	Phenylalanine⁵	Threonine	Tryptophan	Valine	Reference
C. carpio	3.4(1.3/38.5) ^h	6.5(2.5/38.5)	3.9(1.5/38.5)	0.8(0.3/38.5)	3.6(1.4/38.5)	Nose (1979)
I. punctatus	2.0(0.5/24) ⁱ	5.0(1.2/24)	2.2(0.53/24)	0.5(0.12/24)	2.96(0.71/24)	NRC (1983)
O. tshawytscha	4.1(1.7/41) ^j	-	2.2(0.9/40)	0.5(0.2/40)	3.2(1.3/40)	NRC (1983)
O. keta	-	-	3.0(1.2/40)	-	-	Akiyama et al, (1985)
O. keta	-	-	-	0.73(0.29/40)	-	Akiyama et al, (1985a)
O. kisutch	-	-	-	0.5(0.2/40)	-	Klein & Halver (1970)
A. japonica	2.9(1.2/42) ^k	5.2(2.2/42)	3.6(1.5/42)	1.0(0.4/42)	3.6(1.5/42)	Nose (1979)
S. gairdneri	-	-	-	-	-	Kim et al., (1983)
S. gairdneri	-	-	-	-	-	Ketola (1983)
S. gairdneri	-	-	-	-	-	Rumsey et. al. (1983)
S. gairdneri	-	-	-	-	-	Kaushik (1979)
S. gairdneri	-	-	-	-	-	Walton et al, (1982)
S. gairdneri	-	-	-	0.45(0.25/55)	-	Walton et al, (1984)
D. labrax	-	-	-	-	-	Thebault et al., (1985)
O. mossambicus	-	-	-	-	-	Jackson & Capper (1982)
C. carpio	2.9(1.16/40)	-	3.3(1.32/40)	0.6(0.24/40)	2.9(1.16/40)	Ogino (1980a)
S. gairdneri	3.1(1.24/40)	-	3.4(1.36/40)	0.5(0.2/40)	3.1(1.24/40)	Ogino (1980a)

¹ Feeding regime: indicates feeding level and number of feedings per day.
² In the presence of dietary cystine
a 2%;
b 0.24%;
c 1%;
d 1%;
e 0.3%;
f 2%;
g 0.74%;
h 1%
³ In the absence of dietary cystine.
⁴ In the presence of dietary tyrosine
h 1%;
i 1%;
j 0.4%;
k 2%
⁵ In the absence of dietary tyrosine.

(b) Carcass analysis method: Interestingly, recalculation of the data obtained by Ogino (1980a) shows that there is no difference between the relative proportions of individual EAAs required in the diet and the relative proportions of the same 10 EAAs present within the fish carcass (Tacon and Cowey, 1985). A similar relationship has also been seen in the growing pig and chick (Boorman, 1980), and to a lesser extent within the four fish species for which EAA requirements have been determined using amino acid test diets (Fig. 3). Similarly, Wilson and Poe (1985) obtained a regression coefficient of 0.96 when the EAA requirement pattern for the channel catfish was regressed against the whole body EAA pattern found in a 30g channel catfish. Since the amino acid composition of fish body tissue does not differ greatly (if at all) between individual fish species (Njaa and Utne, 1982; Wilson and Cowey, 1985), it follows, therefore, that the pattern of requirement for different species will also be similar. Although not proven, it is not unreasonable to suppose that a similar relationship also exists for shrimps and freshwater prawns. For comparative purposes Table 3 presents the dietary EAA requirement pattern for fish, as determined by Ogino (1980a), together with the carcass EAA pattern of whole fish body tissue, Penaeus japonicus

Figure 3 Relationship between pattern of EAA requirements found by feeding experiments using amino acid test diets with carp (•), Japanese eel (■), channel catfish (□) and chinook salmon (o) and the pattern of the same amino acids in fish carcass. The level of each amino acid is represented as a percentage of the sum of all 10 EAA's in each pattern. The line represents coincidence of requirement and tissue patterns. larvae and juveniles, Penaeus paulensis juveniles, short-necked clam tissue (Venerupis philippinarum; regarded as an excellent and ideal natural food for marine shrimp), and the tail muscle of Macrobrachium rosenbergii. On the basis of the amino acid profiles presented it would appear that shrimp have a higher dietary requirement for arginine, tryptophan and tyrosine, and a lower dietary requirement for valine, threonine and lysine than fish.

Table 3. Mean fish dietary EAA requirement pattern (%) and EAA pattern in body tissue of whole fish, short-necked clam, marine shrimp, and the freshwater prawn.
EAA	Fish requirement (Ogino, 1980a)	Whole body fish tissue (Wilson & Cowey, 1985)	Short-necked clam tissue (Deshimaru et al, 1985)	P. japonicus larvae (Teshima, Kanazawa & Yamashita, 1986)	P. japonicus juveniles (Deshimaru & Shigeno, 1972)	P. Paulensis juveniles (unpublished data)	M. rosenbergii tail muscle (Farmanfarmian & Lauterio, 1980)
Threonine	10.6	9.2	9.6	5.9	8.2	6.7	7.5
Valine	9.5	9.5	8.5	8.8	8.3	13.6	7.3
Methionine	5.4	5.5	5.4	5.7	5.4	7.0	6.5
Isoleucine	7.5	8.0	6.8	9.1	8.6	6.9	7.4
Leucine	13.5	14.6	14.0	12.1	15.0	12.6	14.8
Phenylalanine	9.5	8.3	7.7	8.6	9.0	9.2	7.3
Lysine	16.8	16.9	14.7	13.1	15.8	15.4	17.1
Histidine	4.8	5.2	4.4	4.5	4.5	4.4	4.5
Arginine	11.6	12.3	15.5	14.1	15.2	14.3	20.6
Tryptophan	1.7	1.7	2.7	6.3	NA	NA	NA
Cystine *	2.7	2.0	2.7	2.4	2.1	3.0	NA
Tyrosine *	6.5	6.6	7.8	9.2	7.8	6.7	6.6

NA - data not available (not analysed).
* - Non-essential amino acids.All values are expressed as a percentage of total EAA plus cystine and tyrosine.

In the absence of firm quantitative information on the dietary EAA requirements of shrimp and the majority of farmed fish species, dietary requirement can initially be computed on the basis of the carcass EAA pattern present within 35% of the known dietary protein requirements of the said species; on a general basis EAAs (including the NEAAs cystine and tyrosine) constitute about 35% of the total dietary protein required by fish (Table 2). Thus if a shrimp or fish is known to have a dietary protein requirement of 45%, then dietary EAA requirement would be computed on a carcass EAA pattern of 35% of the dietary protein level. For example, if the carcass EAA pattern for lysine is 16.9% of the total EAA plus cystine and tyrosine present, then dietary requirement level for lysine would be or 2.66% of the dry diet (ie. 45% protein fish ration).

As a guide line Table 4 presents the calculated dietary EAA requirements of fish and shrimp at varying dietary protein levels based on the mean carcass EAA pattern of whole fish tissue and short-necked clam tissue respectively (short-necked clam tissue is used here in the absence of a mean carcass EAA pattern for shrimp).

Table 4. Calculated dietary EAA requirements of fish and shrimp at varying dietary protein levels (values are expressed as a percent of the dry diet)
EAA	Dietary protein level (%)							Carcass EAA pattern (%)
EAA	25	30	35	40	45	50	55	Carcass EAA pattern (%)
FISH								¹
Arginine	1.07	1.29	1.51	1.72	1.94	2.15	2.37	12.3
Histidine	0.45	0.55	0.64	0.73	0.82	0.91	1.00	5.2
Isoleucine	0.70	0.84	0.98	1.12	1.26	1.40	1.54	8.0
Leucine	1.28	1.53	1.79	2.04	2.30	2.55	2.81	14.6
Lysine	1.49	1.77	2.07	2.37	2.66	2.96	3.25	16.9
Methionine	0.48	0.58	0.67	0.77	0.87	0.96	1.06	5.5
Cystine *	0.17	0.21	0.24	0.28	0.31	0.35	0.38	2.0
Phenylalanine	0.73	0.87	1.02	1.16	1.31	1.45	1.60	8.3
Tyrosine *	0.58	0.69	0.81	0.92	1.04	1.15	1.27	6.6
Threonine	0.80	0.97	1.13	1.29	1.45	1.61	1.77	9.2
Tryptophan	0.15	0.18	0.21	0.24	0.27	0.30	0.33	1.7
Valine	0.83	1.00	1.16	1.33	1.50	1.66	1.83	9.5
SHRIMP								²
Arginine	1.36	1.63	1.90	2.17	2.44	2.71	2.98	15.5
Histidine	0.38	0.46	0.54	0.62	0.69	0.77	0.85	4.4
Isoleucine	0.59	0.71	0.83	0.95	1.07	1.19	1.31	6.8
Leucine	1.22	1.47	1.71	1.96	2.20	2.45	2.69	14.0
Lysine	1.29	1.54	1.80	2.06	2.31	2.57	2.83	14.7
Methionine	0.47	0.57	0.66	0.76	0.85	0.95	1.04	5.4
Cystine *	0.24	0.28	0.33	0.38	0.42	0.47	0.52	2.7
Phenylalanine	0.67	0.81	0.94	1.08	1.21	1.35	1.48	7.7
Tyrosine *	0.68	0.82	0.96	1.09	1.23	1.37	1.50	7.8
Threonine	0.84	1.01	1.18	1.34	1.51	1.68	1.85	9.6
Tryptophan	0.24	0.28	0.33	0.38	0.42	0.47	0.52	2.7
Valine	0.74	0.89	1.04	1.19	1.34	1.49	1.64	8.5

¹ Carcass EAA pattern of whole fish tissue (Wilson & Cowey, 1985)
² Carcass EAA pattern of short-necked clam (Deshimaru et al., 1985)
* Non-essential amino acids

2.6.2 Utilization of free amino acids

Fish or juvenile shrimp fed rations in which a significant proportion of the dietary protein is supplied in the form of 'free' or crystalline amino acids generally display sub-optimal growth and feed conversion efficiency compared with animals fed protein-bound amino acids or 'whole' proteins (Wilson et al., 1978; Robinson et al., 1981; Yamada et al., 1981; Walton et al., 1982; Deshimaru, 1981; Deshimaru & Kuroki, 1974a, 1975).

In general, dietary free amino acids are more rapidly assimilated in fish than protein-bound amino acids. Experiments with rainbow trout (Yamada et al., 1981), common carp (Plakas et al., 1980) and tilapia (Oreochromis niloticus; Yamada et al., 1982) fed free amino acid test diets showed that peak plasma amino acid concentrations occurred sooner (12–24h, 2–4h, 2h, respectively) than with an equivalent casein-based diet (24–36h, 4h, 4h, respectively). Furthermore, in carp. individual free amino acids appear to be absorbed at varying rates from the gastro-intestinal tract, and consequently peak plasma concentrations of individual amino acids do not occur simultaneously (Plakas et al., 1980). In juvenile shrimp the situation appears to be the reverse. For example, Deshimaru (1981) showed that the assimilation rate of dietary free arginine into muscle protein by Penaeus japonicus juveniles was extremely low (assimilation less than 0.6%) compared to that of protein-bound arginine (assimilation above 90%). However, although Deshimaru (1981) reported no beneficial effect on growth of free amino acid supplemented diets with P. japonicus juveniles, recent studies have demonstrated that the larvae of the same species is capable of utilizing amino acid supplemented diets for growth (Teshima, Kanazawa & Yamashita, 1986).

For optimal protein synthesis to occur, it is essential that all amino acids (whether they be derived from whole proteins or amino acid supplements) are presented simultaneously to the tissue. If such an equilibrium is not achieved, then amino acid catabolism (breakdown) ensues with consequent loss of growth and and feed efficiency. For those warm water fish species which display a rapid uptake and assimilation of free amino acids, it is therefore essential that either; (1) the release or absorption of free amino acids from the diet is reduced so as to minimise the variations in absorption rate observed between free and protein-bound amino acids (achieved by coating individual amino acids with casein, zein or nylon-protein membranes; Murai et al., 1982; Teshima, Kanazawa & Yamashita, 1986); or (2) that the frequency of feed presentation is increased from two or three feeds per day to up to 18 feeds per day so as to minimise the variations observed in plasma amino acid concentration (Yamada, Tanaka & Katayama, 1981).

2.6.3 Amino acid composition and protein quality

On the basis of the above discussions it is evident that the protein quality of a feed ingredient is dependent upon the amino acid composition of the protein and the biological availability of the amino acids present. In general, the closer the EAA pattern of the protein approximates to the dietary EAA requirement of the species, the higher its nutritional value and utilization. For example, Table 5 presents the 'chemical score' or potential protein value of some commonly used feed proteins. Chemical scores of 100 indicate that the level of a particular EAA within the feed protein is identical to the dietary EAA requirement level for fish (when expressed as a percentage of the total EAAs plus cystine and tyrosine) as determined by Ogino (1980a). The chemical score of the protein is taken to be the percentage of the EAA in greatest deficit relative to the dietary requirement pattern. This method of assessing protein quality is based on the concept that the nutritive value of a protein depends primarily on the amount of the EAA in greatest deficit in that protein, compared to a reference protein (in this case the reference protein is the dietary EAA requirements of fish as determined by Ogino. 1980a). It can be seen from Table 5 that compared to fish meal or fish muscle, which has a well balanced EAA profile and high chemical score (c. 80), the majority of protein sources presented have amino acid imbalances which render them unsuitable as a sole source of dietary protein for fish within complete diets intended for intensive farming systems. The aim of feed formulation is to mix proteins of various qualities to obtain the desired EAA pattern of the fish or shrimp species in question (complete diet feeding).

However, the above relationship between protein quality and EAA pattern will only hold true if the individual amino acids are equally biologically available to the animal. For example, under certain conditions some of the amino acids may be unavailable because the proteins in the diet are incompletely digested. Thus, for carnivorous fish and shrimp species, the cellulose cell wall within plant protein sources may render the proteins present within the cell inaccesible to the digestive enzymes. In other cases, digestion may be hindered by the presence of enzyme inhibitors within the food protein; trypsin inhibitor within raw soybeans. Although it is possible to inactivate these inhibitors by moderate heat processing, under conditions of excessive heat treatment proteins become more resistant to digestion due to peptide bond formation occurring between the side chains of lysine and dicarboxylic acid. The free epsilon amino groups of lysine are particularly susceptible to heat damage, forming addition compounds with non-protein compounds (ie. reducing sugars such as glucose) present in the food stuff (Cockerell, Francis & Halliday, 1972). This reaction is known as the Maillard reaction, and renders the lysine biologically unavailable. Substances other than reducing sugars which are known to react with the free epsilon amino group of lysine include gossypol; phenol based compound present in cottonseed meal. An estimate of the biological availability of amino acids within feed proteins, and hence an indicator of protein quality, can be made by chemically measuring the free or available lysine content of the feed protein (Cowey, 1979).

Table 5. Chemical score and limiting essential amino acids of some commonly used feed proteins ¹
Feedstuffs	Source²	Thr	Val	Met	Cys	Ils	Leu	Phe	Tyr	Lys	His	Arg	Trp	1st limiting amino acid
Chick pea	1	64*	89	63*	104	119	110	113	86	72	100	166	129	Met
Mung bean	1	59*	110	54*	48*	127	121	124	94	79	114	123	123	Cys
Cow pea	1	65*	103	61*	59*	116	116	116	100	75	127	134	129	Cys
Yellow lupin	2	66*	81	20*	126	117	125	85	94	64*	117	192	135	Met
Lima bean	2	84	110	57*	74	135	118	125	106	72	112	98	106	Met
Broad bean	3	77	103	30*	41*	115	118	98	118	77	98	160	118	Met
Haricot bean	1	80	103	43*	67*	120	121	118	83	92	127	104	129	Met
Safflower	2	68*	125	63*	141	111	99	101	100	43*	121	181	118	Lys
Crambe	2	98	121	67*	218	117	104	83	86	66*	104	111	200	Lys
Palm kernel	2	62*	113	94	133	95	89	72	78	41*	98	225	311	Lys
Cottonseed	2	65*	102	52*	118	92	94	122	89	52*	117	205	141	Met/Lys
Sunflower	2	65*	124	83	137	115	104	109	91	42*	119	159	165	Lys
Linseed	2	71	122	93	156	111	90	105	92	43*	100	174	182	Lys
Sesame	2	58*	98	109	148	91	105	86	114	33*	114	211	153	Lys
Coconut	4	65*	114	61*	96	115	112	95	92	37*	81	217	123	Lys
Groundnut	4	55*	99	39*	133	117	100	107	117	53*	100	196	141	Met
Rapeseed	4	93	118	83	70	113	116	94	77	74	131	112	159	Cys
Soybean	4	74	101	46*	130	128	115	105	97	76	106	123	176	Met
Potato protein concentrate	5	89	125	63*	96	128	120	112	149	74	73	73	118	Met
Leaf protein concentrate	6	84	127	57*	56*	112	120	122	129	71	90	96	141	Cys
Spirulina maxima	2	87	136	52*	30*	159	118	105	123	55*	75	111	165	Cys
Saccharomyces cerevisiae	4	93	116	63*	85	139	112	91	108	86	106	89	141	Met
Torulopsis utilis	4	94	118	54*	81	144	98	137	117	84	104	86	118	Met
M. methylotrophus	7	97	134	89	59*	115	107	115	138	71	83	84	118	Cys
Whole hen's egg	8	77	125	100	130	132	109	97	98	78	92	96	135	Thr
Fish muscle	9	83	98	98	85	108	110	80	117	101	121	97	135	Phe
Fish meal (herring)	4	76	127	109	78	117	107	80	95	89	96	111	123	Thr
Fish meal (white)	4	81	106	104	93	121	109	81	94	90	94	116	129	Thr/Phe
Fish protein concentrate	2	83	110	118	63*	127	109	85	103	92	90	95	153	Cys
Fish silage	10	98	122	---72---		101	129	120	94	98	121	108	59*	Trp
Whole shrimp meal	2	83	97	109	85	112	106	95	105	86	73	134	106	His
Meat and bone meal	4	77	128	59*	89	109	113	88	60*	86	100	150	88	Met
Blood meal	4	69*	158	33*	52*	24*	162	124	69*	89	214	62*	123	Ils
Liver meal	2	76	135	72	89	105	121	109	106	71	98	105	153	Lys
Poultry by-product meal	4	76	125	81	141	132	123	80	60*	71	87	134	112	Tyr
Hydrolysed feather meal	4	91	164	24*	289	131	124	78	86	33*	50*	147	76	Met
Worm meal	11	107	99	106	52*	112	124	84	108	79	125	98	82	Cys
House fly larvae	12	75	103	72	52*	96	90	128	218	77	127	82	147	Cys

¹ Scores based on comparison with the mean essential amino acid requirements of rainbow trout andcarp (Ogino, 1980). Mean EAA requirement (expressed as % of total EAA) being: threonine 10.6;valine 9.5; methionine 5.4; cystine 2.7; isoleucine 7.5; leucine 13.5; phenylalanine 9.5;tyrosine 6.5; lysine 16.8; histidine 4.8; arginine 11.6; and tryptophan 1.7

² Source: 1-Kay (1979); 2-Gohl (1980); 3-Bolton and Blair (1977); 4-National Research Council(1983); 5-Tunnel AVEBE Starches Ltd., UK; 6-Cowey et al. (1971); 7-Unpublished data; 8-Coweyand Sargent (1972); 9-Connell and Howgate (1959); 10-Jackson, Kerr and Cowey (1984); 11-Tacon,Stafford and Edwards (1983); 12-Spinelli (1980)

* Limiting essential amino acids (present below 30% mean fish requirement)

2.7 Evaluation of protein quality

Apart from chemically measuring amino acids and their availability within feed proteins, there are many biological methods of evaluating protein quality:

Specific growth rate (SGR) The rate of growth of an animal is a fairly sensitive index of protein quality; under controlled conditions weight gain being proportional to the supply of essential amino acids. Daily SGR can be calculated by using the formula:

Food conversion ratio (FCR) Defined as the grams of feed consumed per gram of body weight gain.


	* As fed basis ie. dry weight
	** Wet or fresh weight gain

Food efficiency (FE) Defined as the grams of weight gained per gram of feed consumed. Units of expression as above.

Protein efficiency ratio (PER) Defined as the grams of weight gained per gram of protein consumed.


	* With this method no allowance is made for maintenance: ie. method assumes that all protein is used for growth.

Apparent net protein utilization (Apparent NPU) Defined as the percentage of ingested protein which is deposited as tissue protein.

where Pb is the total body protein at the end of the feeding trial, Pa is the total body protein at the beginning of the feeding trial, and Pi is the amount of protein consumed over the feeding trial. In this calculation no allowance is made for endogenous protein losses. In contrast to the previous methods of evaluating protein quality, this method requires that a representative sample of animals be sacrificed at the beginning and end of the feeding trial for carcass protein analysis.

The main drawback of these methods of predicting diet or protein quality is that they have to be performed under controlled experimental conditions in the absence of natural food organisms. Consequently, these methods can only be used within intensive or clear water culture systems.

2.8 Nonprotein nitrogenous constituents

Amino acids are important not only as building blocks of protein but as the primary constituents or nitrogen precursors for many nonprotein nitrogencontaining compounds. Table 6 lists some of the more biologically important nonprotein nitrogenous compounds that originate from amino acids.

Table 6. Nonprotein nitrogenous constituents derived from amino acids in animals¹
Nitrogenous compound	Amino acid precursor	Physiological function of compound
Purines & pyrimidines²	Glycine & aspartic acid	Constituents of nucleotides and nucleic acids
Creatine	Glycine & arginine	Energy storage as creatine phosphate in muscle
Bile acids (glycoholic & taurocholic acids)	Glycine & cysteine	Bile acids, aid in fat digestion and absorption
Thyroxine, epinephrine & norepinephrine	Tyrosine	Hormones
Ethanolamine & choline	Serine	Constituents of phospholipids
Histamine	Histidine	A vasodepressor
Serotonin	Tryptophan	Transmission of nerve impulses
Porphyrins	Glycine	Constituents of haemoglobin and cytochromes
Niacin	Tryptophan	Vitamin
Melanin	Tyrosine	Pigment of skin and eyes

¹ Lloyd, McDonald & Crampton (1978)

² Pyrimidine and purine have been suggested to be essential dietary nutrients fornewly hatched fish larvae (Dabrowski & Kaushik, 1982) and Artemia salina (Hernandorena, 1983) respectively.

2.9 Protein and amino acid pathology

2.9.1 Dietary Essential Amino Acid Deficiency

Although all fish examined to date display reduced growth when fed EAA deficient diets, the following additional gross anatomical deficiency signs have been observed under experimental conditions with juvenile fish fed synthetic rations deficient in one or more EAAs:


Limiting EAA	Fish	Deficiency signs¹
Lysine	Salmo gairdneri	Dorsal/caudal fin erosions (1,2); increased mortality (2)
Lysine	Cyprinus carpio	Increased mortality (3)
Methionine	S. gairdneri	Cataract(4,5)
Methionine	Salmo salar	Cataract (6)
Tryptophan	S. gairdneri	Scoliosis² (7–10); lordosis² (7,10); renal calcinosis (8); cataract (7,9); caudal fin erosion; decreased carcass lipid content (9); elevated Ca, Mg, Na and K carcass concentration (7)
Tryptophan	Oncorhynchus nerka	Scoliosis (11)
Miscellaneous	O. keta	Scoliosis/ lordosis (12)
Miscellaneous	C. carpio	Increased mortality and incidence of lordosis observed with dietary defi- ciencies of leucine, isoleucine, lysine, arginine and histidine (3)

¹ 1-Walton, Cowey and Adron (1984); 2-Ketola (1983); 3-Mazid et al. (1978);4-Walton, Cowey and Adron (1982); 5-Poston et al. (1977); 6-Barash, Poston andRumsey (1982); 7-Walton et al. (1984); 8-Kloppel and Post (1975); 9-Poston andRumsey (1983); 10-Shanks, Gahimer and Halver (1962); 11-Halver and Shanks (1960);Akiyama et al. (1985a).

² Curvature of the vertebral column

Under intensive farming conditions dietary EAA deficiencies may arise from one of four possible routes:

Poor feed formulation arising from the use of disproportionate amounts of feed proteins with natural specific EAA deficiencies (Table 5).

Dietary imbalances may also arise from the presence of disproportionate levels of specific amino acids; including leucine/isoleucine antagonisms, and to a lesser extent arginine/lysine and cystine/methionine antagonisms. For example, blood meal is a rich source of valine, leucine and histidine, but is a very poor source of methionine and isoleucine. However, in view of the antagonistic effect of excess leucine on isoleucine, animals fed high dietary levels of blood meal suffer from an isoleucine deficiency caused by an excess of dietary leucine (Taylor, Cole and Lewis, 1977). Although similar antagonisms have also been reported for cystine/ methionine (use of hydrolysed feather meal; Ichhponani and Lodhi, 1976) and arginine/ lysine (Harper, Benevenga and Wohlhueter, 1970) in terrestrial farm animals, they have not been found to occur in fish fed synthetic amino acid diet combinations (Robinson, Wilson and Poe, 1981).
Dietary EAA deficiencies may arise from excessive heat treatment of feed proteins during feed manufacture.
Dietary EAA deficiencies may arise from the chemical treatment of feed proteins with acids (silage production) or alkalies, due to the loss of free tryptophan and lysine/cystine respectively (Kies, 1981).
Dietary EAA deficiencies may arise from the leaching of free and protein bound amino acids into the water. For example, Grabner, Wieser and Lackner (1981) reported the loss, through leaching, of almost all the free and about one-third of the free plus protein bound amino acids from frozen or freezedried zooplankton (Artemia salina and Moina spp.) after a 10 minute water immersion period at 9°C. Considerable losses of water-soluble amino acids have also been observed in carp during mastication (Yamada and Yone, 1986). However, the problem of nutrient leaching of water soluble materials is probably greatest for crustaceans due to their very slow demersal feeding habit and necessity to masticate their food externally prior to ingestion (Farmanfarmaian, Lauterio and Ibe, 1982). For example, Bages and Sloane (1981) reported a 28% loss of dietary protein during the preparation and rehydration of a dry alginate-bound shrimp diet prior to feeding, and a total protein loss of 39–47% after a six hour immersion period in seawater. In general nutrient losses are greater in freshwater than in seawater (Balazs, Ross and Brooks, 1973). However, problems of nutrient leaching can be minimised by using an appropriate feeding regime (ie. regular rather than infrequent feeding; Sedgwick, 1979) and a suitable diet binding or micro-encapsulation technique (Goldblatt, Conklin and Duane Brown, 1980; Jones et al., 1976).

2.9.1 Toxic non-essential amino acids

Nutritional pathologies may also arise from the ingestion of feed proteins containing toxic amino acids. Commonly used feed proteins which are known to contain toxic amino acids include alkali-treated soybean (toxic amino acid - lysinoalanine), the legume Leucaena leucocephala or 'ipil ipil' (toxic amino acid - mimosine), and the faba bean Vicia faba (toxic amino acid - dihydroxyphenylalanine).

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Source: https://www.fao.org/3/ab470e/ab470e02.htm