Available via license: CC BY 4.0
Content may be subject to copyright.
Int. J. Mol. Sci. 2015, 16, 9910-9921; doi:10.3390/ijms16059910
International Journal of
Molecular Sciences
ISSN 1422-0067
www.mdpi.com/journal/ijms
Review
Effects of Dietary Vitamin E on Fertility Functions in
Poultry Species
Deivendran Rengaraj and Yeong Ho Hong *
Department of Animal Science and Technology, Chung-Ang University, Anseong,
Gyeonggi-do 456-756, Korea; E-Mail: deivendran@cau.ac.kr
* Author to whom correspondence should be addressed; E-Mail: yhong@cau.ac.kr;
Tel.: +82-31-670-3025; Fax: +82-31-671-3025.
Academic Editor: Robert J. Norman
Received: 25 February 2015 / Accepted: 24 April 2015 / Published: 30 April 2015
Abstract: Vitamin E is found in high quantities in vegetable oils. Although vitamin E has
multiple functions in humans and animals, its key function is protecting cells from oxidative
damage. Since its discovery, several studies have demonstrated that vitamin E deficiency
causes impaired fertility in humans and lab animals. However, the effects of vitamin E
deficiency or of its supplementation on the fertility of farm animals, particularly on poultry,
are less well studied. Therefore, a comprehensive review of the effects of dietary vitamin E
on the fertility of poultry species is needed in order to understand the beneficial role of
vitamin E in the maintenance of sperm and egg qualities. Based on the observations reviewed
here, we found that a moderate amount of vitamin E in poultry diet significantly protects
semen/sperm qualities in male birds and egg qualities in female birds via decreasing the lipid
peroxidation in semen/sperms and eggs. This review provides an overall understanding of
the effects of dietary vitamin E on fertility functions in poultry species.
Keywords: vitamin E; fertility functions; poultry species
1. Introduction
Vitamins are vital organic compounds that can be obtained in high quantities from vegetable oils.
Vitamin tablets are also commercially available at a reasonable price. To date, thirteen vitamins have
been discovered, named alphabetically vitamin A to vitamin K. The fat-soluble vitamin E was discovered
OPEN ACCESS
Int. J. Mol. Sci. 2015, 16 9911
in the early 1920s by Evans and Bishop [1]. Vitamin E is a generic term for a group of tocopherols and
tocotrienols that have some amount of vitamin activity. Among the four tocopherols (α, β, γ and δ) and
four tocotrienols (α, β, γ and δ) discovered, α-tocopherol is the most biologically active form and
available in high quantities from vegetable oils, unprocessed cereal grains, and nuts [2–5]. Since the first
discovery of vitamin E, numerous investigators have demonstrated the nutritional value of vitamin E in
humans as well as in laboratory and farm animals. Vitamin E is absorbed via the lymphatic pathway and
transported into the systemic circulation in association with chylomicrons [5]. After absorption, vitamin
E is stored chiefly in the liver. Because of its fat-soluble properties it is incorporated in lipid storage
organelles and plasma membranes, therefore it is also widely distributed throughout the body [2,5,6].
Vitamin E interacts with several other dietary components, including selenium, polyunsaturated fatty
acids, sulphur-containing amino acids, other vitamins and minerals, and synthetic antioxidants [7–11].
Vitamin E has multiple critical functions in animals. For instance, it acts as an efficient biological
antioxidant in protecting cells from the adverse effects of reactive oxygen species or free radical
initiators [7,8,10,12]. It is required for the regulation of heme biosynthesis, apparently by controlling
induction and repression of aminolevulinic acid synthase and porphobilinogen synthase [12]. Vitamin E
plays a specific role in the essential transport of amino acids and possibly lipids in the intestine [7].
Vitamin E is also involved in iron metabolism and steroidogenesis [12], and it stimulates humoral and
cellular immune responses against infectious diseases [13].
The symptoms and disorders of vitamin E deficiency vary, depending on the species affected. They
include disorders of the nervous system, skeletal system, circulatory system, muscular system,
cardiovascular system, immune system, and reproductive system [2,10,13]. Furthermore, vitamin E
deficiency may manifest itself in a number of disorders of liver, kidney, and lung, and in adipose
tissue [2]. Vitamin E deficiency may increase the risk of ischemic heart disease, breast cancer, and the
incidence of infections [14], and it promotes susceptibility to dietary and environmental stress in humans
and animals [7,13]. Vitamin E is clinically administered to treat several conditions and diseases in
humans, and complications associated with high dose administrations have been reported [4,14].
Compared to observations in humans, data from animal studies show that vitamin E toxicity is low and
that the vitamin is not mutagenic, carcinogenic, or teratogenic [4].
The activity of vitamin E was first identified as an essential dietary factor for male and female
reproduction in rats [1,15]. Although vitamin E has a broad range of functions in the body, it is primarily
crucial for fertility in humans and livestock species, including poultry. Generally, it has been shown that
vitamin E deficiency causes abnormal spermatogenesis in males and failure to retain zygotes and fetal
resorption in females [5,10,12]. Reproductive functions are crucial for healthy offspring and species
survival of all animals, including poultry. Thus, the objective of this paper is to review studies that have
examined the effects of dietary vitamin E on male and female fertility in poultry species.
2. Vitamin E in Poultry Nutrition
Because vitamin contents vary in western diets, it is important to know the recommended allowances
of vitamins for humans [16]. However, due to many variables, it is very difficult to estimate the optimum
allowances of vitamins for laboratory animal and livestock diets [15]. Dietary supplementation with
vitamin E increases the resistance of animals against infectious diseases and is thus recommended for
Int. J. Mol. Sci. 2015, 16 9912
farm animals including poultry, swine, sheep, and cattle, to meet the increasing demand for meat, eggs,
and milk [13]. The rearing of domesticated birds including chickens, quail, turkeys, ducks, and geese in
poultry farms has been increasing worldwide for the purpose of meat and egg production. Among
the poultry species, chickens are reared in huge numbers, i.e., several billions. Nowadays, modern
poultry feeds are largely supplemented with proteins, carbohydrates, lipids, minerals, and vitamins
to meet the basal nutritional requirements for raising and maintaining healthy birds. The standard
dietary supplementation with proteins, carbohydrates, lipids, minerals, and vitamins supports normal
growth of birds. Similarly, the standard supplementation with certain minerals and vitamins helps to
increase the birds’ immune resistance against pathogenic diseases [17–20]. The dietary requirement for
vitamin E in poultry feed is highly variable and depends on the concentration and type of fat in the
diet, the concentration of selenium, and the presence of pro-oxidants and antioxidants [21]. The National
Research Council’s Committee on Animal Nutrition, USA, provided the nutrient requirements for
poultry species including chickens, turkeys, geese, ducks, pheasants, and quail. According to its
recommendations, poultry feed can be supplemented with 10 IU of vitamin E per kg feed (1 IU = 0.67 mg
dl-α-tocopheryl acetate) for chickens aged up to six weeks, 5 IU/kg feed for chickens aged over
six weeks, 12 IU/kg feed for turkeys aged up to eight weeks, and 10 IU/kg feed for turkeys aged over
eight weeks. For ducks and Japanese quail, feed can be supplemented with 10 IU/kg feed and 12 IU/kg
feed, respectively, for starting and growing birds. The dietary recommendations of vitamin E for poultry
species during laying and breeding vary slightly [21]. Vitamin E is one of the essential nutrients in
poultry feed, and its deficiency causes a wide variety of disorders in poultry species (Figure 1). These
include nutritional muscular dystrophy that affects striated muscles, erythrocyte hemolysis that affects
erythrocytes, and exudative diathesis that affects capillary walls. Furthermore, vitamin E deficiency
can lead to membrane lipid peroxidation, affecting hepatic mitochondria and microsomes, as well as to
an accumulation of ceroid in adipose tissues, and to cerebellar encephalomalacia in chickens [7,10,12].
In addition, vitamin E deficiency impairs feather development in chickens [10]. Vitamin E deficiency
causes gizzard myopathy in turkeys and ducks, and an accumulation of ceroid in turkeys [10].
Figure 1. Commonly known vitamin E deficiency diseases and most vulnerable tissues in
poultry species.
Int. J. Mol. Sci. 2015, 16 9913
3. Effects of Dietary Vitamin E on Male Fertility Functions in Poultry Species
Since the first study on reproductive functions in rats by Evans and Bishop [1], several investigators
have demonstrated the benefits of dietary supplementation with vitamin E on fertility in different animal
species. In this chapter, we will review the effects of vitamin E supplementation specifically on fertility
functions in male birds, based on evidence provided by several significant studies. Male fertility is
principally related to semen and sperm qualities, including the volume of semen, concentration of sperms
in the semen, sperm viability, sperm motility, sperm forward progression, and the sperm fertilizing
capacity. These qualities can be affected by several environmental factors and endocrine disrupting
chemicals, which may enter the body through diet, respiration, and skin contact [22]. The resulting
adverse effects may be partially controlled or averted by clinical treatments or by dietary supplementation
with certain beneficiary compounds, including minerals, vitamins, and antioxidants. Linoleic acid is one
of the essential polyunsaturated fatty acids that cannot be produced de novo in vertebrates. If an animal
diet is rich in any polyunsaturated fatty acids, the addition of an antioxidant is required in order to avoid
peroxidation of the fatty acids [23]. Arscott and colleagues [24] fed adult male White Leghorn (WL)
chickens with diets containing high levels of linoleic acid (7.3%) and an either low (4.3 mg/kg feed) or
high (166.3 mg/kg feed) amount of vitamin E for 25 weeks. The males fed with diets high in linoleic
acid and low in vitamin E showed impaired fertilizing capacity and sperm concentration in the semen.
However, diet supplementation with a high amount of vitamin E prevented these adverse effects. The
semen volume, hatchability of fertile eggs, and weight of the testes were not affected by any of the above
diets. Furthermore, the authors suggested that vitamin E acts as an antioxidant that protects chickens
against encephalomalacia by preventing the breakdown of linoleic acid to 12-oxo-cis-9-octadecenoic
acid (keto acid). Encephalomalacia is a vitamin E deficiency disease, which readily occurs in chickens
fed on a diet containing high levels of polyunsaturated fatty acids of the linoleic acid series and low
levels of vitamin E [25]. In another study, Arscott and Parker [26] fed male chickens with a diet high in
linoleic acid (7.3%) and low in vitamin E (4.3 mg/kg diet) from hatch to 28 weeks of age, and high in
both linoleic acid (7.3%) and vitamin E (166.3 mg/kg diet) from 28 to 40 weeks. As a result, the adverse
effects on fertility and semen concentration were restored in chickens fed on the diet high in vitamin E.
Thus, the adverse effects of linoleic acid on male fertility are not permanent but can be reversed
by vitamin E supplementation. Another compound, dilauryl succinate, does not contain peroxide or
polyunsaturated fatty acids, however, similar to linoleic acid, it induces encephalomalacia in chickens.
In a study by Yoshida and Hoshii [27], fertility of WL roosters fed on a diet containing 12% dilauryl
succinate for 16 weeks was significantly low. When the roosters were fed a diet containing 12% dilauryl
succinate and 200 mg/kg dl-α-tocopheryl acetate, the sperm fertilizing capacity was significantly high.
Avian spermatozoa are rich in polyunsaturated fatty acids, in particular in docosatetraenoic acid and
arachidonic acid [28,29]. The high proportions of polyunsaturated fatty acids provide membrane
flexibility, which is essential for sperm mobility and sperm-egg fusion [30]. However, because of their
high levels of polyunsaturated fatty acids, avian sperms are also very sensitive to reactive oxygen
species, causing male infertility [28,31,32]. Therefore, an increased antioxidant status in semen or
spermatozoa is a prerequisite for the prevention of male infertility. In a study by Surai and
colleagues [31], six-month-old male Rhode Island Red chickens were fed with a diet containing 0, 20,
200, or 1000 mg/kg α-tocopheryl acetate for eight weeks. During the final two weeks, they observed that
Int. J. Mol. Sci. 2015, 16 9914
the concentration of vitamin E in semen and sperms had doubled, and the susceptibility of the semen to
lipid peroxidation was decreased, in particular in birds fed with 200 mg/kg of vitamin E. In another
study [33], 30-week-old WL roosters were fed with a basal diet high in fish/soybean oil and with or
without supplementation of vitamin E (30, 200, or 400 mg/kg). After 38 weeks, the roosters fed with
fish/soybean oil showed the lowest total antioxidant status in the semen. However, the addition of
vitamin E to the fish/soybean oil diet resulted in an increase in semen volume, motility, and sperm
potency at 38 weeks. Zaniboni and colleagues [32] allowed male turkeys to feed on a basal diet
supplemented with 60 mg/kg of α-tocopheryl acetate from 26 to 39 weeks of age. From 40 to 60 weeks,
the turkeys were allowed to feed on the basal diet additionally supplemented with 60 mg α-tocopheryl
acetate and 2% fish oil. As a result, the α-tocopheryl status in the turkey semen was increased two-fold.
Biswas and colleagues fed Indian native Kadaknath male chicks with a basal diet supplemented with 10,
100, or 200 mg/kg dl-α-tocopheryl acetate from hatch to 30 weeks of age. An analysis performed during
the final three weeks of the trial revealed that the proportion of abnormal and dead spermatozoa was
significantly lower and the fertilizing capacity was significantly higher in birds fed with 100 mg/kg of
vitamin E. Moreover, the vitamin E status of semen and spermatozoa was higher in birds fed with
100 mg/kg of vitamin E than that in birds fed with 10 mg/kg of vitamin E [34]. These studies suggest
that an increased antioxidant status of semen or sperm is based on an increase in the antioxidant content
of the diet. In another study, Biswas and colleagues fed male Japanese quail with a basal diet containing
15 IU, 150 IU, or 300 IU of dl-α-tocopheryl acetate per kg feed, from the age of one day for up to
25 weeks. During these dietary trials, plasma testosterone concentration, testicular weight, as well as
semen volume were not significantly changed. However, the percentage of abnormal and dead sperms
was significantly lower, and the sperm capacity was higher in quail fed with a diet containing 150 IU/kg
of vitamin E [35]. In a similar study, Hooda and colleagues fed male Japanese quail with a basal diet
supplemented with different concentrations of vitamin E (0–300 IU dl-α-tocopheryl acetate/kg feed)
from the age of five weeks onwards, for 10 to 13 weeks. Among the different concentrations of
vitamin E, 75 IU/kg feed elicited the best result in protecting the male fertility functions in quail [36].
Taken together, these studies, in particular those by Surai et al., Biswas et al., and Hooda et al. suggest
that a moderate level of vitamin E is best for maintaining the fertility functions in male chickens
and quail [31,34–36].
Selenium is a trace element and frequently added to animal diet as a supplement for the maintenance
of reproductive functions, and a deficiency in dietary selenium causes a decrease in sperm concentration,
sperm motility, and sperm capacity in humans, lab animals, and farm animals, including poultry
species [37,38]. Selenium is a component of selenoproteins, such as glutathione peroxidase, which
protect sperms against oxidative damage [39,40]. It is well known that vitamin E interacts with selenium,
and that both play a role in the maintenance of reproductive functions as well as in the reduction of
reactive oxygen species and free radical generation [7,8]. Surai and colleagues fed Rhode Island Red
males with a balanced diet supplemented with selenium (0.3 mg/kg diet) and vitamin E (20 or 200 mg/kg
diet) and observed that the activity of glutathione peroxidase in testes, semen, and sperms was
significantly increased [41]. Compared to chickens and quail, geese exhibit lower semen quality, egg
production, and fertility and hatchability rates. When three-year-old White Koluda male geese were
fed with a control diet and an experimental diet supplemented with 0.3 mg/kg feed of selenium
and 100 mg/kg feed of vitamin E, the semen volume and sperm concentrations in the semen were
Int. J. Mol. Sci. 2015, 16 9915
significantly increased (1.5- and 1.7-fold, respectively) during the next reproductive season, in the
males fed on the experimental diet. Also, the level of lipid peroxidation was significantly lower in
males fed on the experimental diet [42]. The study by Jerysz and Lukaszewicz suggests that combined
supplementation with selenium and vitamin E enhances the reproductive functions of certain avian
species that naturally show low reproductive behavior. Antioxidant supplementation is not only
important for lipid-containing poultry feed but also a prerequisite for any basal diet in order to maintain
fertility. In a study by Lin and colleagues [43], freshly hatched Taiwan Native male chicks were fed
with maize/soybean diets for up to 23 weeks of age. After 23 weeks, the birds were allowed to feed on
maize/soybean diets supplemented with 80 mg/kg feed of dl-α-tocopheryl acetate for up to 52 weeks of
age. Males fed with the vitamin E supplemented diet showed significantly higher sperm viability,
sperm motility, and sperm concentration in the semen. This study suggests that a maize/soybean
containing diet is inadequate for maintaining the fertility functions in male birds, thus vitamin E
supplementation is required.
Molting in birds is a periodic occurrence, during which, at least once a year, the feathers are replaced.
Molting is commonly associated with hens. However, several studies reported that molting in males
might lead to an improved semen quality [30,44]. Molting in male birds can be experimentally induced
by withdrawal of feed, water, or both, or by dietary manipulation with imbalanced minerals such as
sodium, calcium, iodine, and zinc [30,44]. Khan and colleagues [45] induced molting in WL male birds
with a basal diet containing 3000 mg zinc oxide per kg feed. After two weeks of molting, the birds were
fed with either a basal diet or a diet supplemented with vitamin E (100 IU/kg feed). At least three weeks
after the trial, the semen volume, sperm motility, and sperm capacity in fertilizing eggs had significantly
increased in birds fed with the vitamin E supplemented diet, compared to the control group. Several
investigators have demonstrated the association of vitamin E deficiency with impaired male reproductive
functions. It has been identified as an anti-sterility vitamin, and its deficiency or long-term omission in
the diet causes abnormal spermatogenesis and affects the semen qualities, including sperm viability,
sperm motility, and sperm capacity [5,10,12]. Earlier studies reported that testicular degeneration
resulted when Rhode Island Red males were fed a vitamin E deficient diet for two years [23,24]. From
the studies reviewed above, it has been understood that dietary supplementation with vitamin E protects
semen quality, especially by preventing the breakdown of polyunsaturated fatty acids, which can cause
oxidative damage. The recommended amount of vitamin E in poultry diet for maintaining male fertility
functions can vary, depending on the investigator. For instance, Khan et al. recommended that
a poultry diet should contain at least 10 mg vitamin E per kg of feed [45]. However, several studies
recommended that a poultry diet should contain a moderate amount (not very low and not very high) of
vitamin E [31,34–36].
4. Effects of Dietary Vitamin E on Female Fertility Functions in Poultry Species
This chapter will review the effects of dietary vitamin E supplementation on female fertility functions
in different poultry species, based on the evidence provided by several significant studies. The fertility
functions of females, like those of males, are crucial for successful production of healthy offspring. More
specifically, in poultry species the daily egg production, the egg quality, including egg weight and
components of the yolk and albumin, and the egg fertility and hatchability are the most important factors
Int. J. Mol. Sci. 2015, 16 9916
that determine healthy offspring. The number of fertile eggs produced for hatching dictates the ultimate
profitability of hens [46]. The nutrients required for embryo development are derived mainly from the
yolk and albumin stored in the eggs. A chicken egg contains significant amounts of nutrients, including
carbohydrates, proteins, lipids, vitamins, and trace elements, and these nutrients can be increased or
decreased in eggs by altering the dietary composition. The concentrations of total lipids, including the
polyunsaturated fatty acids of the linoleic acid series, and of antioxidants are relatively stable in the eggs
of chickens fed with a standard diet, but they are subject to alteration by major changes in dietary nutrient
composition [47,48]. Similar to Arscott’s study in males [24], Machlin and colleagues [23] fed WL hens
with a basal diet high in linoleic acid (7%) and low in vitamin E (20 IU/pound feed) for eight weeks. By
the end of this period, egg production had decreased from 78% to 25%. Only 37% of the eggs were
fertile, and none of the fertile eggs was hatched. When hens were fed with a diet containing high amounts
of both linoleic acid (7%) and vitamin E (100 IU/pound feed) for eight weeks, the egg production reached
an average of 57%. Seventy-six percent of the eggs were fertile and 67% of the fertile eggs were hatched.
Together with the results obtained for males [24], this study suggests that vitamin E acts as an
antioxidant, in that it protects female fertility by preventing the breakdown of linoleic acid, which would
then lead to oxidative damage. Additionally, the study by Machlin and colleagues showed that hens fed
with diets low in linoleic acid do not require additional vitamin E or antioxidants for maintenance of egg
production, fertility, and hatch of fertile eggs [23]. When Yoshida and Hoshii fed WL hens with a basal
diet containing 12% dilauryl succinate, which has similar effects as linoleic acid, the fertility of eggs and
the hatchability of fertile eggs were observed to be low. However, these effects were prevented by adding
200 mg/kg feed of dl-α-tocopheryl acetate to the same diet, containing 12% dilauryl succinate [27].
Vicine, an alkaloid found in high quantities in faba beans (Vicia faba L.), has a marked influence on
the metabolism of laying hens. Dietary vicine causes peroxidation of cellular components, resulting in
abnormal lipid transport and a decrease in fertility. In a study by Muduuli et al., laying WL hens fed
with a vicine containing diet showed decreased egg weight, fertility, and hatchability. However, vitamin E
supplementation slightly increased the egg weight and markedly protected fertility and hatchability of
eggs [49]. This study clearly indicates that the antioxidant property of vitamin E is very helpful in
reducing the adverse effects of toxic compounds like vicine. Similarly to the observations reviewed
above, an adequate amount of vitamin E was found necessary in the poultry diet for maintaining female
fertility, regardless of whether or not the diet is high in polyunsaturated fatty acids. In a study by
Lin et al. [48], hatched Taiwan Native female chicks were fed with a maize/soybean diet for up to
17 weeks of age. After 17 weeks, the birds were allowed to feed on a maize/soybean diet supplemented
with 80 mg/kg feed of dl-α-tocopheryl acetate for up to 46 weeks of age. As a result, hens fed with the
vitamin E supplemented diet showed a better performance in egg production and egg mass. Likewise,
vitamin E supplemented diet showed a better performance in fertility (over 7%) and hatchability (over
13%). In another study, Hooda and colleagues fed five-week-old male and female Japanese quail with a
basal diet containing different concentrations of vitamin E (0, 75, 150, 225, and 300 IU dl-α-tocopheryl
acetate/kg feed), during a period of 5 to 13 weeks of age. Then, the males and females were allowed to
mate in different groups: control males with control females, control males with females on vitamin E
supplemented diets, and control females with males on vitamin E supplemented diets. As a result, males
paired with females after both had been fed with a vitamin E supplemented diet led to slightly better
fertility and hatchability of quail eggs. However, these results were not influenced by an increase in
Int. J. Mol. Sci. 2015, 16 9917
dietary vitamin E [36]. When Japanese quail were maintained on a soybean meal diet containing low
levels of vitamin E (2 IU/kg diet) for 35 weeks, the percentage of fertile eggs was significantly decreased
and the hatchability of fertile eggs was severely affected. However, no other clinical symptoms were
observed [50]. Kling and Soares suggested that this much lower amount of vitamin E in the diet is
extremely inadequate for supporting normal reproduction in quail.
In avian species, the sperms are stored for a short period in male reproductive tract (vas deferens).
Following natural mating or artificial insemination, the ejaculated sperms undergo a selection process
and the selected sperms are stored for a prolonged period in female reproductive tract at two sperm
storage sites [51–53]. The primary storage site is found in the utero-vaginal junction, and the secondary
storage site is found in the lower portion of the infundibulum [52,53]. Studies by Breque and colleagues
indicate a positive effect of dietary vitamin E on the antioxidant status of sperm storage sites in hens [53].
In avian species, the proportion of sperms found particularly at utero-vaginal junction significantly
correlate with the sperms found at perivitelline layer of eggs [52,54,55]. Moreover, Brillard and Antoine
suggest that hen’s egg achieves 100% of fertility when the perivitelline layer contains 1440 or more
sperms [54]. Taken together, it is well understood that vitamin E deficiency significantly affects the
fertility of female poultry species [5,12]. If the hatched chicks show vitamin E deficiency symptoms,
the amount of vitamin E in eggs should be increased through supplementation of the maternal diet.
In addition, the amount of vitamin E in the diet should be correlated with the amount of dietary selenium
and polyunsaturated fatty acids. If the poultry diet contains a sufficient amount of selenium and is not
rich in polyunsaturated fatty acids, about 20 mg vitamin E per kg diet is required for maintaining
fertilization rate of breeding hens [56]. In addition, Yoshida and Hoshii recommended an amount of
more than 500 μg vitamin E per egg to ensure the hatching of healthy chicks [27]. The main effects of
dietary vitamin E supplementation on male and female fertility in poultry are shown in Figure 2.
From analyses of male and female birds, it has been understood that feeding the birds with at least 100 mg
vitamin E per kg diet can prevent vitamin E deficiency problems.
Figure 2. The main effects of dietary vitamin E supplementation on male and female fertility
functions in poultry species.
Int. J. Mol. Sci. 2015, 16 9918
5. Conclusions and Future Perspectives
In this communication, we reviewed the effects of dietary antioxidant vitamin E on fertility of male
and female poultry species. The review suggests that a moderate vitamin E supplementation of a
balanced poultry diet significantly maintains male fertility functions, including semen volume, sperm
concentration, sperm viability, sperm motility, and sperm capacity, in poultry species. In addition,
a moderate vitamin E diet supplementation significantly maintains female fertility in poultry species,
including egg production, egg fertility, and egg hatchability. It has been understood that the maintenance
of fertility in male and female birds by vitamin E is based on its property as a defense mechanism against
oxidative damage, which predominantly results from the breakdown of polyunsaturated fatty acids.
Furthermore, the deficiency or long-term omission of vitamin E in the diet impairs male and female
fertility in birds. Based on the information discussed here, this review suggests a few future perspectives
for research on poultry species. (1) Most studies referring to poultry species have focused on the effects
of dietary vitamin E on semen and sperm qualities in males, and egg qualities in females. However, the
effects on Leydig cells and Sertoli cells in males, and on theca cells and granulosa cells in females need
to be elucidated; (2) The effects of vitamin E deficiency or supplementation on male and female
steroidogenesis are not well understood; (3) The effects of vitamin E deficiency or supplementation on
the functions of fertility-associated genes and proteins need to be elucidated; (4) Most studies
recommended a moderate amount of vitamin E (75–100 mg/kg diet) for the maintenance of fertility
functions in male and female birds. In agreement with these suggestions, the National Research
Council’s Committee on Animal Nutrition should establish a recommended allowance; (5) Most
studies referring to the fertility of poultry species have focused on the interaction of vitamin E with
polyunsaturated fatty acids and selenium, however, the interaction of vitamin E with other vitamins and
minerals are less well known. Collectively, this review provides an overall understanding of the effects
of dietary vitamin E on fertility of diverse poultry species.
Acknowledgments
This Project was supported by the National Research Foundation grant (NRF-2010-0009360),
Republic of Korea.
Author Contributions
Deivendran Rengaraj and Yeong Ho Hong have equally participated in the planning and drafting of
this manuscript, and have read and approved the submitted and final version of this manuscript.
Conflicts of Interest
The authors declare no conflict of interest.
References
1. Evans, H.M.; Bishop, K.S. On the existence of a hitherto unrecognized dietary factor essential for
reproduction. Science 1922, 56, 650–651.
Int. J. Mol. Sci. 2015, 16 9919
2. Herting, D.C. Perspective on vitamin E. Am. J. Clin. Nutr. 1966, 19, 210–218.
3. Horwitt, M.K. The promotion of vitamin E. J. Nutr. 1986, 116, 1371–1377.
4. Bendich, A.; Machlin, L.J. Safety of oral intake of vitamin E. Am. J. Clin. Nutr. 1988, 48, 612–619.
5. Bjorneboe, A.; Bjorneboe, G.E.; Drevon, C.A. Absorption, transport and distribution of vitamin E.
J. Nutr. 1990, 120, 233–242.
6. Wang, X.; Quinn, P.J. Vitamin E and its function in membranes. Prog. Lipid Res. 1999, 38,
309–336.
7. Green, J. Vitamin E and the biological antioxidant theory. Ann. N. Y. Acad. Sci. 1972, 203, 29–44.
8. Tappel, A.L. Selenium-glutathione peroxidase and vitamin E. Am. J. Clin. Nutr. 1974, 27, 960–965.
9. Debry, G. Polyunsaturated fatty acids and vitamin E: Their importance in human nutrition.
Ann. Nutr. Aliment. 1980, 34, 337–350.
10. Combs, G.F. Assessment of vitamin E status in animals and man. Proc. Nutr. Soc. 1981, 40, 187–194.
11. Chen, L.H. Interaction of vitamin E and ascorbic acid (review). In Vivo 1989, 3, 199–209.
12. Nair, P.P. Vitamin E and metabolic regulation. Ann. N. Y. Acad. Sci. 1972, 203, 53–61.
13. Tengerdy, R.P. Vitamin E, immune response, and disease resistance. Ann. N. Y. Acad. Sci. 1989,
570, 335–344.
14. Machlin, L.J. Clinical uses of vitamin E. Acta Vitaminol. Enzymol. 1985, 7, 33–43.
15. Putnam, M.E.; Comben, N. Vitamin E. Vet. Rec. 1987, 121, 541–545.
16. Morton, R.A. Vitamins in western diets. Proc. Nutr. Soc. 1976, 35, 23–29.
17. Tengerdy, R.P.; Heinzerling, R.H.; Nockels, C.F. Effect of vitamin E on the immune response of
hypoxic and normal chickens. Infect. Immun. 1972, 5, 987–989.
18. Lucas, I.A. The use of antibiotics as feed additives for farm animals. Proc. Nutr. Soc. 1972, 31, 1–8.
19. Wilgus, H.S. Disease, nutrition—Interaction. Poult. Sci. 1980, 59, 771–781.
20. Latshaw, J.D. Nutrition—Mechanisms of immunosuppression. Vet. Immunol. Immunopathol. 1991,
30, 111–120.
21. National Research Council. Nutrient Requirements of Poultry, 9th revised ed.; The National
Academies Press: Washington, DC, USA, 1994; pp. 1–157.
22. Rengaraj, D.; Kwon, W.S.; Pang, M.G. Effects of motor vehicle exhaust on male reproductive
function and associated proteins. J. Proteome Res. 2015, 14, 22–37.
23. Machlin, L.J.; Gordon, R.S.; Marr, J.E.; Pope, C.W. Effect of antioxidants and unsaturated fatty
acids on reproduction in the hen. J. Nutr. 1962, 76, 284–290.
24. Arscott, G.H.; Parker, J.E.; Dickinson, E.M. Effect of dietary linoleic acid, vitamin E and
ethoxyguin on fertility of male chickens. J. Nutr. 1965, 87, 63–68.
25. Mokadi, S.; Budowski, P. Relationship between vitamin E and encephalomalacia in chicks.
Br. J. Nutr. 1963, 17, 347–355.
26. Arscott, G.H.; Parker, J.E. Effectiveness of vitamin E in reversing sterility of male chickens fed
a diet high in linoleic acid. J. Nutr. 1967, 91, 219–222.
27. Yoshida, M.; Hoshii, H. Effect of dilauryl succinate on reproduction of the cock and hen and
preventive effect of vitamin E. J. Nutr. 1976, 106, 1184–1191.
28. Surai, P.F.; Noble, R.C.; Sparks, N.H.C.; Speake, B.K. Effect of long-term supplementation with
arachidonic or docosahexaenoic acids on sperm production in the broiler chicken. J. Reprod. Fertil.
2000, 120, 257–264.
Int. J. Mol. Sci. 2015, 16 9920
29. Surai, P.F.; Fujihara, N.; Speake, B.K.; Brillard, J.P.; Wishart, G.J.; Sparks, N.H.C. Polyunsaturated
fatty acids, lipid peroxidation and antioxidant protection in avian semen. Asian-Australas.
J. Anim. Sci. 2001, 14, 1024–1050.
30. Khan, R.U.; Nikousefat, Z.; Javdani, M.; Tufarelli, V.; Laudadio, V. Zinc-induced moulting:
Production and physiology. World Poult. Sci. J. 2011, 67, 497–505.
31. Surai, P.F.; Kutz, E.; Wishart, G.J.; Noble, R.C.; Speake, B.K. The relationship between the dietary
provision of α-tocopherol and the concentration of this vitamin in the semen of chicken: Effects on
lipid composition and susceptibility to peroxidation. J. Reprod. Fertil. 1997, 110, 47–51.
32. Zaniboni, L.; Rizzi, R.; Cerolini, S. Combined effect of DHA and α-tocopherol enrichment on
sperm quality and fertility in the turkey. Theriogenology 2006, 65, 1813–1827.
33. Zanini, S.F.; Torres, C.A.; Bragagnolo, N.; Turatti, J.M.; Silva, M.G.; Zanini, M.S. Evaluation of
the ratio of ω6:ω3 fatty acids and vitamin E levels in the diet on the reproductive performance of
cockerels. Arch. Tierernahr. 2003, 57, 429–442.
34. Biswas, A.; Mohan, J.; Sastry, K.V. Effect of higher dietary vitamin E concentrations on physical
and biochemical characteristics of semen in Kadaknath cockerels. Br. Poult. Sci. 2009, 50, 733–738.
35. Biswas, A.; Mohan, J.; Sastry, K.V.; Tyagi, J.S. Effect of dietary vitamin E on the cloacal gland,
foam and semen characteristics of male Japanese quail. Theriogenology 2007, 67, 259–263.
36. Hooda, S.; Tyagi, P.K.; Mohan, J.; Mandal, A.B.; Elangovan, A.V.; Pramod, K.T. Effects of
supplemental vitamin E in diet of Japanese quail on male reproduction, fertility and hatchability.
Br. Poult. Sci. 2007, 48, 104–110.
37. Young, V.R.; Nahapetian, A.; Janghorbani, M. Selenium bioavailability with reference to
human-nutrition. Am. J. Clin. Nutr. 1982, 35, 1076–1088.
38. Hansen, J.C.; Deguchi, Y. Selenium and fertility in animals and man—A review. Acta Vet. Scand.
1996, 37, 19–30.
39. Neve, J.; Vertongen, F.; Molle, L. Selenium deficiency. Clin. Endocrinol. Metab. 1985, 14, 629–656.
40. Ahsan, U.; Kamran, Z.; Raza, I.; Ahmad, S.; Babar, W.; Riaz, M.H.; Iqbal, Z. Role of selenium in
male reproduction—A review. Anim. Reprod. Sci. 2014, 146, 55–62.
41. Surai, P.; Kostjuk, I.; Wishart, G.; Macpherson, A.; Speake, B.; Noble, R.; Ionov, I.; Kutz, E. Effect
of vitamin E and selenium supplementation of cockerel diets on glutathione peroxidase activity
and lipid peroxidation susceptibility in sperm, testes, and liver. Biol. Trace Elem. Res. 1998, 64,
119–132.
42. Jerysz, A.; Lukaszewicz, E. Effect of dietary selenium and vitamin E on ganders’ response to semen
collection and ejaculate characteristics. Biol. Trace Elem. Res. 2013, 153, 196–204.
43. Lin, Y.F.; Chang, S.J.; Yang, J.R.; Lee, Y.P.; Hsu, A.L. Effects of supplemental vitamin E
during the mature period on the reproduction performance of Taiwan native chicken cockerels.
Br. Poult. Sci. 2005, 46, 366–373.
44. Woodard, A.E.; Ogasawara, F.X.; Snyder, R.L.; Stinnett, V. Effect of forced molting on quantity
and quality of semen in turkey breeder males as influenced by diet. Poult. Sci. 1975, 54, 2094–2101.
45. Khan, R.U.; Rahman, Z.U.; Javed, I.; Muhammad, F. Effect of vitamins, probiotics and protein on
semen traits in post-molt male broiler breeders. Anim. Reprod. Sci. 2012, 135, 85–90.
46. Khan, R.U. Antioxidants and poultry semen quality. Worlds Poult. Sci. J. 2011, 67, 297–308.
Int. J. Mol. Sci. 2015, 16 9921
47. Posati, L.P.; Kinsella, J.E.; Watt, B.K. Comprehensive evaluation of fatty acids in foods. III. Eggs
and egg products. J. Am. Diet. Assoc. 1975, 67, 111–115.
48. Lin, Y.F.; Chang, S.J.; Hsu, A.L. Effects of supplemental vitamin E during the laying period on the
reproductive performance of Taiwan native chickens. Br. Poult. Sci. 2004, 45, 807–814.
49. Muduuli, D.S.; Marquardt, R.R.; Guenter, W. Effect of dietary vicine and vitamin E
supplementation on the productive performance of growing and laying chickens. Br. J. Nutr. 1982,
47, 53–60.
50. Kling, L.J.; Soares, J.H., Jr. Vitamin E deficiency in the Japanese quail. Poult. Sci. 1980, 59,
2352–2354.
51. Bakst, M.R. Sperm recovery from oviducts of turkeys at known intervals after insemination and
oviposition. J. Reprod. Fertil. 1981, 62, 159–164.
52. Brillard, J.P. Sperm storage and transport following natural mating and artificial-insemination.
Poult. Sci. 1993, 72, 923–928.
53. Breque, C.; Surai, P.; Brillard, J.P. Roles of antioxidants on prolonged storage of avian spermatozoa
in vivo and in vitro. Mol. Reprod. Dev. 2003, 66, 314–323.
54. Brillard, J.P.; Antoine, H. Storage of sperm in the uterovaginal junction and its incidence on the
numbers of spermatozoa present in the perivitelline layer of hens eggs. Br. Poult. Sci. 1990, 31,
635–644.
55. Brillard, J.P.; Bakst, M.R. Quantification of spermatozoa in the sperm-storage tubules of turkey
hens and the relation to sperm numbers in the perivitelline layer of eggs. Biol. Reprod. 1990, 43,
271–275.
56. Hennig, A.; Marckwardt, E.; Richter, G. Relations between vitamin-E supply and the fertility of
hens. Arch. Tierernahr. 1986, 36, 519–529.
© 2015 by the authors; licensee MDPI, Basel, Switzerland. This article is an open access article
distributed under the terms and conditions of the Creative Commons Attribution license
(http://creativecommons.org/licenses/by/4.0/).