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Infant Formula: Closer So ihe Reference, edited bv
Niels C. R. Raiha and Firmino F! Rubaltelli. Nestle
Nutrition Workshop Series. Pediatric Program,
Vol. 47 Supplement. Nestec Ltd.. Vevey/Lippincott
Williams & Wilkins. Philadelphia © 2002.
Role and Function of Nucleotides
in Infant Nutrition
Julio J. Boza and *Olga Martinez-Augustin
Department of Nutrition, Nestle Research Center. Lausanne, Switzerland; and ^Department
of Biochemistry and Molecular Biology, University of Granada, Granada, Spain
Nucleotides are low-molecular-weight biologic compounds that play a major part in
almost all biologic processes. Their main roles include the following (1-3):
• Nucleic acid precursors: nucleotides make up the monomeric units of DNA and
RNA.
• Energy-transfer molecules: adenosine triphosphate (ATP) is the major source of
cellular chemical energy.
• Physiologic mediators: cyclic adenosine monophosphate (cAMP) acts as second
messenger; cyclic guanosine monophosphate (cGMP) regulates many cellular
events; adenosine is known to be a potent vasodilator; guanosine triphosphate
(GTP) is involved in signal transduction, etc.
• Activated intermediates: for example, uridine diphosphoglucose (UDP glucose) is
an intermediate in glycogen and glycoprotein synthesis, and other nucleotides are
intermediates in the synthesis of phospholipids and serve as methyl sulfate donors.
• Structural components of coenzymes: such as nicotinamide adenine dinucleotide
(NAD), flavin adenine dinucleotide (FAD), and coenzyme A (CoA), involved in
many metabolic pathways.
• Allosteric effectors: controlling the regulatory steps of major metabolic pathways.
• Cellular agonists: extracellular nucleotides trigger intracellular signal-transduction
cascades including the cAMP and inositol-calcium pathways.
METABOLISM OF NUCLEOTIDES
Cell nucleic acids and nucleotides are continuously synthesized, degraded, and salvaged, particularly in tissues with a rapid cellular turnover such as the gut and the immune system. Nucleotide pools are derived from three potential sources: de novo synthesis, salvage (recycling of preformed bases and interconversion into the desired
compound), and the diet. The relative contributions of the salvage pathway and the
diet to this pool in vivo are poorly understood.
165
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NUCLEOTIDES IN INFANT NUTRITION
De Novo Synthesis and Catabolism of Nucleotides
There is a close relation between amino acid metabolism and nucleotide base synthesis. Nucleotides contain either a purine or a pyrimidine base (nitrogen-containing
bases). Almost all the atoms in both kinds of bases are derived directly or indirectly
from amino acids. Thus the purine core of adenosine and guanine is synthesized de
novo in mammalian cells from glycine, aspartate, glutamine, tetrahydrofolate derivatives, and CO 2 . The first step is the formation of phosphoribosylpyrophosphate
(PRPP) from ribose-5-phosphate and ATP. PRPP and glutamine are then involved in
a condensation reaction catalyzed by PRPP aminotransferase, an enzyme that is inhibited by feedback from AMP and GMP, so that the synthesis is governed by the
needs of the cell. After 10 steps, monophosphates are converted into di- and triphosphates.
The pyrimidine ring is synthesized de novo in mammalian cells from aspartate,
glutamine, and CO2. In this pathway, the ring is formed first, and then the sugar phosphate is added. The first reaction in pyrimidine synthesis is the formation of carbamoyl phosphate from glutamine and CO2. Subsequent steps yield orotate, which
reacts with PRPP (the ribose-5-phosphate donor) to render ornithine monophosphate
(OMP). Uridine monophosphate (UMP) is then synthesized by OMP decarboxylation. Uridine triphosphate (UTP), cytidine triphosphate (CTP), and deoxyderivatives
are obtained from UMP.
Uric acid is the end product of purine base catabolism in primates and humans,
whereas other species can convert it to more soluble catabolites. The end products of
pyrimidine base catabolism are |3-alanine (from cytidine and uracil) and (3aminoisobutyrate (from thymine). Both are soluble, easily excreted products.
The Salvage Pathway
The endogenous supply of nucleotides is maintained through both the de novo synthesis described earlier and through a salvage pathway, a mechanism to recover the
bases resulting from endogenous nucleotide and nucleic acid breakdown present in
many cell types. This pathway might be enhanced when nucleotides are provided by
the diet and is much less energy consuming for the cell than is the de novo process
(4). Thus an exogenous source of nucleotides, such as dietary supplements, that
spares the cost of the de novo synthesis may be especially important during the period of rapid growth experienced by young infants.
There are not enough data regarding the relative contribution of each of the
three potential sources {de novo, salvage, and the diet) to the body's pools, or how
this contribution changes depending either on the tissue studied or on the special
metabolic conditions. Two important questions have to be answered: first, whether
there is a need for dietary nucleotide supplementation; and second, the extent
to which the different sources of nucleotides are used under given metabolic conditions.
NUCLEOTIDES IN INFANT NUTRITION
167
Contribution of Dietary Nucleotides
Dietary nucleotides contribute to the salvage pathway by providing preformed nucleosides and nitrogenous bases. Nucleotides are ingested in the form of nucleoproteins, from which nucleic acids are liberated in the intestinal tract by the action of
proteases. After this, pancreatic nucleases degrade nucleic acids to a mixture of
mono-, di-, tri-, and polynucleotides. Phosphoesterases supplement the action of
these nucleases, producing mononucleotides that are converted into nucleosides by
the action of intestinal alkaline phosphatase. Finally, nucleosidases release the sugar
moiety, yielding free nitrogenous bases. The evidence suggests that a mixture of nucleosides and nitrogenous bases is offered to the enterocyte for absorption (5). Figure
1 summarizes the digestion of nucleoproteins and the absorption of nucleosides.
Absorption and Metabolism of Dietary Nucleotides
Dietary nucleotides are absorbed mainly as nucleosides by a combination of a highly
efficient Na+-dependent active transport and facilitated diffusion. It appears that nucleosides are predominately absorbed in the upper part of the small intestine. Two
facts support this observation: first, the cells of this part of the small intestine have,
Lumen
Enterocyte
Nucleoproteins
^ Proteases
Nucleic acids
1 Nucleases/Phosphoesterases
Nucleotides
Nucleotides
Alk.phosphatases
NUCLEOSIDES
NUCLEOSIDES
Nucleosidases
Purines and Pyrimidines
•
Bases
FIG. 1. Digestion and absorption of nucleic acids and related products.
168
NUCLEOTIDES IN INFANT NUTRITION
in general, the greatest absorptive capacity; second, several studies have suggested
that these cells have a low capacity for de novo synthesis (6—8).
Experiments carried out in healthy mature animals have shown that 90% of the ingested nucleotides are absorbed. Nevertheless, there is growing evidence that in the
process of absorption, dietary nucleotides are extensively metabolized in the gastrointestinal and liver tissues before their entry into the systemic circulation. In fact,
experiments carried out with rats have shown that only 5% of the absorbed purines
are incorporated into intestinal nucleic acids, and a relatively small amount appears
in hepatic cells (7-9). Similar results were obtained by Simmonds et al. (10,11) when
free guanine was added to the diet of pigs, and only minor incorporation into pig tissues was found (< 1 %).
Stable isotope approaches in mice, using 13C nucleotides, also have shown that
purine nucleotides undergo almost complete degradation during their passage
through the enterocytes (12). In this study, the contributions of dietary nucleotides to
RNA synthesis in vivo were estimated by feeding pregnant mice a diet containing
[13C]-labeled nucleotides for 5 days. It was found that only 0-0.2% of tissue RNA
purine nucleotides came from the diet, whereas this incorporation percentage reached
4% in the case of uridine incorporation into hepatic and mucosal RNA. These results
are in agreement with in vitro studies carried out by He et al. (13) in which the uptake and transport of nucleosides were studied in intestinal cell lines (Caco-2 and
IEC-6). After a 2-hour incubation with radiolabeled cytidine or uridine, a small
amount of transported pyrimidine nucleoside (10-15%) was detected from both directions in the cell monolayer (apical to basolateral and basolateral to apical),
whereas the purine nucleoside could not be detected. It was therefore concluded that
the metabolism of radiolabeled cytidine was complete during transport. These studies show that, although dietary purines are metabolized during absorption, a modest
but perhaps critically important fraction of dietary uridine does become incorporated
into nucleic acid. It is tempting to speculate that this might represent a specific and
functionally important fraction or subfraction of RNA.
In general, all the experiments summarized earlier are in agreement with the observation (14) that in well-nourished animals, the de novo synthesis of both purines
and pyrimidines from amino acid precursors is capable of supporting the cellular
needs for nucleic acid synthesis.
It has been suggested that when protein intake is reduced, salvage of nucleotides
is increased. Boza et al. (15) showed that the incorporation of purine nucleotides into
RNA of Caco-2 cells is rather limited, but it becomes important when cells are nutritionally stressed by glutamine deprivation. Animal studies also support this hypothesis. In a recent study, mice infected with Staphylococcus aureus and fed a proteinfree diet showed a higher RNA content in small intestinal cells when a mixture of
nucleosides was administered intraperitoneally (16). Based on these observations as
well as many others discussed later, it has been proposed that nucleotides behave as
"semiessential" or "conditionally" essential nutrients (17,18). These nutrients may
became essential when the endogenous supply is insufficient for normal function,
even though their absence from the diet does not lead to a classic clinical deficiency
NUCLEOT1DES IN INFANT NUTRITION
169
syndrome. Therefore, not only when protein intake is decreased but also in situations
in which there is an increased demand for nucleotide synthesis (after gut injury, sepsis, or surgical trauma, or during rapid growth such as in pregnancy and the neonatal
period), some tissues with a rapid turnover, such as the gut and the immune system,
may increase the salvage of exogenous nucleotides by reducing their catabolism.
This hypothesis is supported by several studies suggesting that nucleotide supplementation of diets may be of clinical significance.
BIOLOGIC EFFECTS OF DIETARY NUCLEOTIDES
Gastrointestinal Effects
Intestinal Growth and Development
The involvement of dietary nucleotides in intestinal growth and maturation has been
extensively documented (19-21). Thus Uauy et al. (19) found that the administration
of nucleosides (0.8% wt/wt of diet) to weanling rats over a 2-week period increased
the DNA content, villous height, and maltase activity when compared those in with
rats fed a nucleotide-free diet. Carver (20) also reported an increase in small bowel
weight (as a percentage of body weight) as well as of weight/length ratio in weanling
mice fed a 0.21% (wt/wt) nucleotide-supplemented diet; however, disaccharidase activities were not affected. Other studies carried out in adult rats have shown that deprivation of dietary nucleotides diminishes the activity of enzymatic markers of villous tip cell differentiation, whereas nucleotide supplementation increases
brush-border enzymatic activities in the same cells. No significant changes were observed in the crypts (21).
Recovery after Injury
The effects described are much more pronounced in the case of animals recovering
after gut injury induced by exposure to sublethal radiation doses (22) or after lactoseinduced chronic diarrhea (23). In the former study, nucleotide supplementation of the
rat diet (0.8% wt/wt) over a 10-day period was correlated with a decrease in animal
mortality and intestinal inflammation, and with higher maltase- and sucrase-specific
activities in the jejunum and ileum. However, no differences were shown for mucosal
protein or DNA content, villous height, and so on. In the latter study, rats fed a nucleotide-supplemented diet (0.25% wt/wt) over a 4-week period showed higher levels of intestinal maltase and sucrase activity compared with rats fed a nonsupplemented diet. A greater villous height-to-crypt depth ratio and reduced numbers of
intraepithelial lymphocytes also were observed in the rats fed the nucleotide-supplemented diet.
Starvation and refeeding with nucleotide-free diets also have been shown to alter
the intestinal mucosa. Thus adult rats subjected to starvation for 5 days and later
given a nucleotide-free diet showed slower normalization in the jejunum and incomplete normalization of differentiation markers in the ileum (24). Nucleotide
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NUCLEOTIDES IN INFANT NUTRITION
supplementation of the diet caused increased mucosal weight in the jejunum and
ileum, with an increase in protein and DNA content and brush-border enzyme activity. However, this nucleotide supplementation did not lead to any striking changes in
nonstarved control rats. It is well known that removing intraluminal nutrient supply
and giving parenteral nutrition retards cell turnover and induces atrophy and dysfunction, but Tsujinaka et al. (25) recently showed that supplementation of total parenteral nutrition (TPN) solutions with nucleotides improved mucosal permeability in
rats. All these findings imply that dietary nucleotides may be important for rapid cell
replication at a time of increased need.
There is evidence that dietary nucleotides also may have an effect on healing in the
human intestinal mucosa. In a clinical trial on small-for-gestational age neonates
whose intestinal mucosa was shown to be functionally impaired by intrauterine malnutrition, babies fed a formula supplemented with nucleotides gained more weight
and length and had a greater head circumference than did those fed a nucleotide-free
formula (26). Dietary nucleotide supplementation also promoted healing of small
bowel ulcers in experimental ileitis in rats after the intraperitoneal administration of
indomethacin (27). However, these same investigators have recently shown that dietary nucleotides aggravate dextran sulfate sodium-induced distal colitis in rats by
enhancing the concentration of proinflammatory cytokines and myeloperoxidasespecific activity in the colon (28).
It has been shown that nucleotides are involved in small intestinal maturation during TPN and prevent TPN-associated intestinal atrophy (29,30). The addition of a
source of purines and pyrimidines to a standard TPN regimen in rats stimulates the
proliferative activity of crypt cells, as assessed by mucosal wet weight, DNA and
RNA content, villous height, and maltase- and sucrase-specific activities.
Gut Microflora
It is well known that the intestinal microflora of breast-fed infants is different from
that of infants fed cow's milk formula. Bifidobacteria usually predominate in the gut
of breast-fed infants, whereas gram-negative bacteria are the predominant microorganisms in infants fed cow's milk formula.
Gil et al. (31) carried out a study to determine the effects of nucleotide supplementation of an adapted formula on the microbial pattern of the feces in newborn
term infants. No differences in bacterial counts could be demonstrated after 1 or 4
weeks. Only when the values were expressed as percentages of total fecal bacterial
counts could slight differences be observed between supplemented and unsupplemented formulas, with a higher percentage of bifidobacteria and a lower percentage of enterobacteria in the feces of infants fed the supplemented formula. However, the percentages remained very different in both cases from those in breast-fed
infants. This lack of influence of nucleotide supplementation on the fecal flora was
confirmed in a similar but larger study with a higher level of nucleotide supplementation (32). No advantage of nucleotide supplementation could be found at ages
2, 4, or 7 weeks.
NUCLEOTIDES IN INFANT NUTRITION
171
Hepatic Effects
The liver has a large capacity for nucleotide synthesis; it is believed to be the supplier
of nucleosides for other tissues. Nevertheless, dietary nucleotide deprivation impairs
liver structure and function. Thus Novak et al. (33) reported that weanling mice fed
a nucleotide-free diet had decreased liver weight and glycogen content, and increased
hepatic cholesterol, liver phosphorus, and serum bilirubin, when compared with animals fed a nucleotide-supplemented diet (0.21% wt/wt). Lopez-Navarro et al. (34)
showed that deprivation of dietary nucleotides changes the morphology of the hepatocyte, and demonstrated both nuclear and cytosolic alterations. This same group
found a decrease in protein synthesis in the liver as well as in the small intestine in
adult rats fed a nucleotide-free diet for 7 days (35).
The role of nucleotides on liver regeneration after injury has been assessed by using hepatectomy or different models of chemically induced cirrhosis. Ogoshi et al.
(36,37) reported that a parenterally administered nucleotide/nucleoside mixture
(10% of amino acid nitrogen) improved hepatic function and promoted an earlier
restoration of nitrogen balance after liver injury or 70% hepatectomy in rats. Gil's
group in Granada (38,39) carried out two studies in rats made cirrhotic by thioacetamide administration. These investigators concluded that dietary nucleotide supplementation is decisive in ensuring hepatocyte recovery after liver damage, by attenuating the inflammatory reaction, interfering with collagen metabolism
(antifibrotic properties), and correcting plasma and liver microsomal fatty acid profile. Therefore it would appear that the repair and growth of the liver, a major organ
of purine and pyrimidine biosynthesis, can be improved by providing an external
supply of preformed nucleotides and nucleosides.
Effects on Immunity
Like the intestine, the immune system is a rapidly dividing tissue. The role of nucleotides in immune tissue has recently become evident. Although the mechanism is
not known, dietary nucleotides may contribute to the pool of nucleotides available to
proliferating lymphocytes, which turn over rapidly and thus have increased nucleotide
requirements. The levels of various enzymes involved in nucleotide metabolism vary
with different stages of lymphocyte activation or function, and salvage of exogenous
purines and pyrimidines is increased in activated lymphocytes, in which de novo
purine and pyrimidine biosynthesis also is dramatically increased (40,41). Increased
intracellular nucleotide pools and the expression of large numbers of transmembrane
nucleoside transporters are consequences of inducing lymphocyte proliferation (1).
Cellular Immunity
Many effects of dietary nucleotides on cellular immunity have been described. The
main ones are as follows:
• Lymphocytes from animals fed a nucleotide-free formula have a significantly decreased proliferative response to mitogens (42).
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NUCLEOTIDES IN INFANT NUTRITION
• Nucleotide-free diets lead to a decrease in interleukin-2 (IL-2) production in response to mitogens in mice. The addition of either uracil or RNA to the diet corrects this. The effect is much more marked in animals recovering from protein-energy malnutrition (43,44).
• Dietary nucleotides influence the delayed-type cutaneous hypersensitivity response by maintaining the T-helper cell population in the murine spleen (45,46).
• Nucleotide-free diets produce a decrease in the phagocytic capacity of murine
macrophages (47).
In most of these studies, the addition of RNA or uracil restores immune function,
and this may be related to the suggested limited capacity of rapidly proliferating lymphocytes to salvage pyrimidines (48).
• Mice fed diets containing nucleotides have a greater resistance to challenge with S.
aureus and Candida albicans (49). In contrast, oral RNA or intraperitoneally administered individual nucleosides have no effect against methicillin-resistant S. aureus infection in mice (50).
• The addition of nucleoside-nucleotide mixtures improves gut morphology and reduces the incidence of bacterial translocation in protein-deficient mice (51).
• Dietary nucleotides partially counteract the immunosuppressive effects of dexamethasone in Cryptosporidium parvum-challenged mice (52).
• Dietary nucleotides and nucleosides aggravate colonic damage and inflammation
in chemically induced experimental colitis in rats (53).
Humoral Immunity
The effects of nucleotides on humoral immunity are as follows:
• Mice fed a nucleotide-free diet show a depressed humoral response to T celldependent antigens, an effect that is reversed by the addition of a nucleotidenucleoside mixture to the diet (54).
• RNA supplementation of cell-culture media leads to (a) increased antibody production to T cell-dependent antigens in murine spleen cells (55), and (b) increased
immunoglobulin G (IgG) and IgM levels in response to T cell-dependent stimuli
in mononuclear cells from human peripheral blood (56).
Human Infant Studies
As discussed earlier, there is evidence from both animal studies and in vitro studies
that the inclusion of either nucleic acids or nucleotides in the diet can be beneficial
for immune and gastrointestinal function under conditions in which there is an increased demand for nucleotide synthesis. In light of this, several studies have been
carried out on the impact of dietary nucleotides in both preterm and term newborn infants and in children with malnutrition or diarrhea.
The capacity of mononuclear cells to exert natural killer (NK) cell activity (cytotoxic lymphocytes) and to produce IL-2 was investigated by Carver et al. (57). Term
NUCLE0T1DES IN INFANT NUTRITION
173
infants were either exclusively breast-fed (n = 9), fed a nucleotide enriched formula
(SMA + ,n = 13), or fed the same formula without added nucleotides (SMA~,« = 15),
for 4 months. The nucleotide supplementation levels per liter in SMA + were 12 |xmol
AMP, 6 |xmol GMP, 6 |xmol inosine monophosphate (IMP), 62 (xmol cytidine
monophosphate (CMP), and 15 |xmol UMP. During the study, mothers recorded the
duration of infections as well as the highest temperature reached during any illness.
Both the incidence and the severity of infections were very low, with no differences
between dietary groups. Red blood cell and hematocrit values did not differ between
the groups. NK cell activity was greater in breast-fed infants and infants fed the nucleotide-supplemented formula than in infants fed the unsupplemented formula at age
2 months, whereas at 4 months, no difference was found. IL-2 production at age 2
months was greater with the nucleotide-supplemented formula, the values being similar to those of the breast-fed group. At 4 months, no differences in IL-2 production
were found between the formula groups.
Another way to study the response of the immune system to dietary nucleotides is
to assess the immune response to vaccination. Pickering etal. (58) carried out a study
on newborn infants receiving either a conventional formula (n = 107) or the same
formula supplemented with nucleotides (Similac Advance, n = 101) for 12 months.
A third group of infants (n = 103) was exclusively breast-fed for 2 months, and then
fed with human milk or the conventional formula until age 12 months. The immunization schedule recommended by the American Academy of Pediatrics was followed: Haemophilus influenzae type B (HIB), diphtheria-pertussis-tetanus (DPT),
and oral poliovirus vaccine (OPV) were given at age 2 and 4 months, followed by
DPT and HIB at 6 months. The vaccine response, assessed by HIB and diphtheria antibody titers, was greater at age 7 months in children receiving the nucleotide-supplemented formula than in those receiving the unsupplemented formula. The higher
HIB antibody titer persisted in the nucleotide-supplemented group at 12 months. The
nucleotide-supplemented group had higher HIB antibody concentrations throughout
the study than did children fed human milk for <6 months, but the values were not
different from those fed human milk for >6 months. The enhanced responses to diphtheria and HIB are consistent with an effect on T cell-dependent responses.
However, the mechanisms whereby dietary nucleotides enhance the antibody responses to HIB or diphtheria remain unknown.
Martinez-Augustin et al. (59) evaluated the influence of dietary nucleotide supplementation on the intestinal permeability to lactulose/mannitol and to (3-lactoglobulin and a-casein in preterm infants during the first month of life. Of the 27
preterm infants enrolled in the study, 11 were fed a standard low-birthweight milk
formula, and 16 were fed the same formula supplemented with nucleotides at levels similar to those found in human milk. Blood and urine samples were obtained
at ages 1, 7, and 30 days. Neither the intestinal permeability to saccharides nor the
intestinal absorption of p-lactoglobulin or a-casein was affected by the addition of
nucleotides to the formula. However, serum concentrations of IgG to (3-lactoglobulin at age 30 days were higher in preterm neonates fed the supplemented formula
than in those fed the control formula. The authors concluded that nucleotide
174
NUCLEOTIDES IN INFANT NUTRITION
supplementation might be beneficial in achieving optimal maturation of the immune system.
Another study (60) evaluated the influence of dietary nucleotide supplementation
on total immunoglobulin levels in preterm infants, following a similar protocol to
that described earlier. Twelve infants received a standard low-birthweight milk formula, and 12 received the same formula supplemented with nucleotides at levels similar to those found in human milk. Serum samples were obtained at ages 10 and
20-30 days and 3 months. Cord blood also was obtained. Cord blood levels of IgG
were lower than described in normal term neonates, corresponding to the low transfer time of maternal IgG across the placenta. During the first 3 months of postnatal
life, a significant decrease in IgG was observed in both groups, but no differences
were detected at any time between the two formula groups. Serum IgM concentrations showed a completely different pattern: low levels of this immunoglobulin were
detected in cord blood, whereas a progressive increase in IgM concentration with age
was observed. At ages 20-30 days, as well as at 3 months, higher IgM concentrations
were detected in the serum of infants fed the nucleotide-supplemented formula than
in those fed on the conventional formula. IgA was reported in the serum only after
20-30 days because of the low concentrations before this time. The levels were increased at 3 months, especially in infants fed the supplemented formula.
Recently Martfnez-Augustin et al. (60) evaluated the influence of dietary supplementation on the recovery of infected and malnourished children with diarrhea.
Twenty-two children younger than 3 years (mean age, 17.1 months) admitted to the
Hospital Albina R. de Patino (Cochabamba, Bolivia) because of persistent diarrhea
(for >15 days) were included in the study. Children were randomly assigned to a
control group (n = 11), which received a formula without nucleotides added (Nieda),
or to an experimental group (n = 11), which received the same formula supplemented with nucleotides. Blood samples were obtained at the beginning of the study
and 3 weeks after recovery. Total IgG, IgA, and IgM and specific IgG against (3-lactoglobulin and a-casein were determined. Refeeding after malnutrition did not produce any significant changes in either specific or total IgG concentrations. Serum IgA
decreased significantly during the refeeding period in infants fed the nucleotide-supplemented formula. In contrast, serum IgM increased during this period, and significant differences were found in the group fed the standard formula. However, no differences were related to the nucleotide supplementation.
These results are consistent with a previous study that showed that healthy infants
consuming a nucleotide-fortified formula (n = 194) for 3 months experienced fewer
first episodes of diarrhea than did those fed a control formula (n = 190) (61).
However, the investigators found that neither the characteristics of the episodes (hospital admission rate, total number of episodes, total number of days with diarrhea, duration of episodes) nor the pattern of enteropathogens isolated was affected.
NUCLEOTIDES IN HUMAN MILK
Nucleic acids in human milk are likely to originate from intact or lysed cells contained in the milk. Indeed colostrum, which contains many more cells than does
NUCLEOT1DES IN INFANT NUTRITION
175
mature milk, has a much higher nucleic acid concentration. Human milk contains significant amounts of preformed nucleotides. At least 13 different acid-soluble nucleotides have been found, of which pyrimidine nucleotides represent the most abundant fraction (62,63). The nucleotide composition of human milk differs appreciably
from that of other species. For example, cow's milk-based infant formulas contain
significant quantities of orotic acid, whereas this nucleotide cannot be found in human milk. It has been shown that high levels of dietary orotic acid cause fatty liver;
however, this effect is unique to the rat (64,65).
As much as 25% of the total nitrogen in human milk is nonprotein nitrogen (66).
This fraction of human milk has been partially characterized and includes compounds such as urea, free amino acids, nucleic acids, nucleotides, peptides, amino
sugars, creatinine, creatine, amino alcohols, uric acid, ammonia, carnitine, and
polyamines. Several of these nitrogenous compounds have been recognized as modulators of important neonatal physiologic functions and play specific roles in neonatal development (67,68).
Nucleotides are reported to account for 0.5-5% of human milk nonprotein nitrogen, ranging from 4 to >70 mg/1. Most of the nucleotides contained in human milk
are monophosphates (AMP, GMP, IMP, CMP, and UMP) and diphosphates [adenosine diphosphate (ADP), guanosine diphosphate (GDP), inosine diphosphate (IDP),
cytidine diphosphate (CDP), and uridine diphosphate (UDP)]. However, the nucleotide composition of human milk is very complex. In addition to mono- and dinucleotides, combinations of nucleotides with other components such as hexoses, Nacetyl-exosamines, and cyclic nucleotides are encountered.
Table 1 shows the mean nucleotide content of human milk at 2,4, 8, and 12 weeks
of lactation, as reported by Janas and Picciano (63). Five lactating women were followed up longitudinally. The cytidine and uridine nucleotides measured in this study
comprised the first and second largest fractions, respectively, of the total nucleotide
content. Progression of lactation is accompanied by a decrease in the levels of CMP
and AMP, whereas levels of IMP increase (Table 1).
TABLE 1. Nucleotide content of human milk
Week of lactation
Nucleotide
2 wk
4 wk
8 wk
12 wk
Mean
CMP
UMP
AMP
IMP
GMP
UDP
CDP
ADP
GDP
18.5
5.5
7.1
4.6
3.2
3.9
9.7
2.8
2.2
16.5
8.0
5.0
6.4
4.2
4.5
10.6
1.9
2.1
13.0
4.3
4.5
6.6
3.4
3.8
15.1
1.0
2.2
10.0
4.4
4.2
8.4
4.6
5.0
11.4
1.0
2.2
14.4
5.5
5.1
6.6
3.9
4.3
11.8
1.6
2.2
Values expressed as (unol/l.
ADP, adenosine diphosphate; AMP, adenosine monophosphate; CDP, cytidine diphosphate;
CMP, cytidine monophosphate; GDP, guanosine diphosphate; GMP, guanosine monophosphate; IMP, inosine monophosphate; UDP, uridine diphosphate; UMP, uridine monophosphate.
From Janas and Picciano (63).
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NUCLEOTIDES IN INFANT NUTRITION
TABLE 2. Nucleotide contents of human colostrum and mature milk
Stage of lactation
Nucleotide
CMP
UMP
AMP
GMP
GDP-mannose
UDP-Achexosamines
UDP-hexoses
UDP
2d
6d
15d
1 mo
3 mo
55.1
17.7
33.4
3.3
3.9
9.7
2.8
2.2
31.0
14.9
22.4
5.0
4.5
10.6
1.9
2.1
26.4
7.0
26.0
—
3.8
15.1
1.0
2.2
18.7
13.9
20.2
3.2
5.0
11.4
1.0
2.2
18.3
9.3
15.1
—
4.3
11.8
1.6
2.2
Values expressed as (j.mol/1.
AMP, adenosine monophosphate; CMP, cytidine monophosphate; GDP, guanosine diphosphate; GMP, guanosine monophosphate; UDP, uridine diphosphate; UMP, uridine monophosphate.
From Gil and Sanchez de Medina (62).
The nucleotide content of human milk was compared with that of colostrum in a
study by Gil et al. (62). Pooled colostrum and mature milk from four women was analyzed. Human milk at 3 months of lactation contained —63 |xmol/l of nucleotides—
that is, —50% of the amount of nucleotides present in human colostrum. The results
presented in Table 2 show a decrease of nucleotide concentration with advancing lactation (Table 2).
Leach et al. (69) recently introduced the concept of total potentially available nucleotides (TPAN). In their opinion, nucleotide quantification of human milk should
include measurement of polymeric nucleotides (nucleic acids), nucleosides, and nucleotides containing adducts. They used three different types of enzymatic hydrolysis, involving nuclease PI (to convert polymeric nucleotides into mononucleotides),
nucleotide pyrophosphatase (to release nucleotides from adducts), and alkaline phosphatase (to release the nucleosides). This complete enzymatic digestion is a reasonably accurate reflection of the in vivo process and allows the measurement of the entire nucleotide fraction of human milk. The authors analyzed >100 individual
samples from four different European sites at different stages of lactation. Table 3
TABLE 3. Potentially available nucleosides and total potential available nucleotides in pooled
human milk by stage of lactation
Stage of lactation
Nucleoside
2d
3-1 Od
1 mo
3 mo
Mean (range)
Cytidine
Uridine
Guanosine
Adenosine
TPANs
71
26
21
21
137
86
32
30
29
177
102
48
45
46
240
96
47
28
31
202
88(33-146)
38 (21-67)
31 (19-92)
32(13-97)
189(82-402)
Values expressed as (xmol/l.
TPANs, total potential available nucleotides.
From Leach et al. (69).
NUCLEOTIDES IN INFANT NUTRITION
177
TABLE 4. Percentage of total potentially available nucleosides in pooled human milk as
adducts, polymeric nucleotides, monomeric nucleotides, and nucleosides
Percentage of total
Nucleoside
Polymeric NTs
Monomeric NTs
Nucleosides
Adducts
Cytidine
57
37
5
1
±
±
±
±
12
13
5
1
Uridine
19
36
18
27
±
±
±
±
7
12
14
12
Guanosine
59
34
1
7
±21
± 14
±2
± 15
Adenosine
TPANs
47 ± 11
35 ± 10
5±4
13 ± 9
48 ± 8
36 ± 10
8±6
9 ± 4
NTs, nucleotides; TPANs, total potential available nucleotides.
From Leach et al. (69).
shows the mean values for each nitrogenous base at different stages of lactation, expressed as nucleoside equivalents as well as TPAN. The mean TPAN of pooled samples was lowest in colostrum, but showed no consistent upward or downward trend
in transitional milk, early mature milk, or late mature milk. Using the process described earlier, Leach et al. (69) were able to determine the percentage of nucleotides
found in human milk as poly- or monomeric nucleotides, nucleosides, or adducts.
The amount of each nucleoside found in each form and the amounts of each form
contributing to the TPAN are shown in Tables 3 and 4.
The nucleotides in these samples were present in predominantly polymeric and
monomeric forms. Consistently, only low concentrations of nucleoside and adducts
were present, uridine being the predominant nitrogenous base in this nucleotide fraction. Using the percentages and values of TPAN in human milk (Table 3), is possible to calculate the free nucleotide concentrations in this study. These are (per liter)
33 |xmol cytidine nucleotide, 14 (xmol uridine nucleotide, 10 |xmol guanosine nucleotide, and 11 (j,mol adenosine nucleotide, for an average total of 68 (xmol nucleotides/1. This calculation includes the contribution of mono-, di-, and triphosphonucleotides. Janas and Picciano (63) measured mono- and diphosphonucleotide
concentrations and reported mean values (per liter) of 26.2 jjimol cytidine nucleotide,
9.8 |xmol uridine nucleotide, 6.1 ji,mol guanosine nucleotide, and 6.7 |xmol adenosine nucleotide, for an average total of 55.2 |xmol nucleotides/1 (including inosine
monophosphate). The study by Janas and Picciano is the only one reporting consistent data on IMP concentrations. Leach et al. (69) suggested that the reason for this
may be the action of adenosine deaminase (present in human milk), which converts
adenosine to inosine. If this enzyme acts in vitro, the absence of inosine could constitute a sample preparation artifact.
The most recent characterization of the nucleotide content of human milk is that
carried out by Thorell et al. (70), who analyzed the concentration of nucleic acids and
ribonucleotide metabolites in the milk of 14 mothers at 3-24 weeks of lactation.
Expressed as nucleotide equivalents, 68 ± 55 u.mol/1 was present as nucleic acid, 84
± 25 (jumol/1 as nucleotides, and 10 ± 2 |xmol/l as nucleosides. As previously described, the nucleotide/nucleoside profile showed a substantial predominance of
pyrimidines, and uric acid also was found in high concentrations. Enzymes capable
of degrading nucleotides in the milk were found in this study, suggesting that the
/ 78
NUCLE0T1DES IN INFANT NUTRITION
TABLE 5. Nucleotide content of human milk (n.mol/1) (mean ± SEM) changes in nucleotide
levels after incubation of human milk
Compound
Nucleic acida
CMP
UMP
GMP
AMP
Cytidine
Uridine
Inosine
Guanosine
Adenosine
Guanine
Hypoxanthine
Xanthine
Uric acid
Fresh milk
(n = 14)
68
66
11
1.5
5.7
5.4
4.9
± 55
± 19
±5.3
± 1.6
± 4.9
± 1.6
± 1.3
—
—
—
0.8 ± 1.3
—
—
69 ± 12
24 h/23°C
(n = 3)
4 h/37°C
(n = 1)
NM
-9.7
-7.0
-3.3
-8.3
+6.0
+ 12.5
—
—
—
+2.6
—
—
+ 11.4
NM
-4.8
-5.1
—
-1.7
+ 11
+ 15
—
—
—
—
-0.8
+3.8
+6.5
Values expressed as ixmol/l, mean ± SEM.
a
Nucleic acids expressed as nucleotide equivalents.
AMP, adenosine monophosphate; CMP, cytidine monophosphate; GMP, guanosine
monophosphate; NM, not measured; UMP, uridine monophosphate.
nucleotide profile could have been affected by catalysis during storage of the milk in
the breast. Incubation of fresh human milk for 24 hours at 23°C caused partial transformation of CMP and UMP to cytidine and uridine, respectively. GMP and AMP
were partly transformed to guanine and uric acid. This indicates that human milk contains the complete set of enzymes necessary to convert purine nucleotides to uric
acid. However, pyrimidine nucleotides remained as nucleotides or nucleosides
(Table 5).
Thorell et al. (70) also incubated fresh human milk (for 4 hours at 37°C) with a fetal small intestine homogenate to simulate the physiologic digestion of nucleotides.
Again the metabolic products of this digestion were mainly cytidine, uridine, and uric
acid (Table 5). In conclusion, pyrimidine nucleotides are partially degraded during
storage in the breast and digestion in the small intestine. The products of these
processes are cytidine and uridine (pyrimidine nucleosides), which are readily absorbed in the small intestine. Conversely, purine nucleotides also are partially degraded during storage in the breast and digestion in the small intestine, so they are
found mainly as uric acid, the final metabolic end product of purine catabolism,
which is excreted and cannot be used further. Thus the bioavailability of pyrimidine
nucleotides seems to be substantially greater than that of purine nucleotides. These
results are in agreement with those obtained in vivo by Boza et al. (12,71), who quantified the incorporation of exogenous nucleotides into murine tissue RNA when nucleotides were included in the diet. As we pointed out earlier, they observed that 4%
of tissue RNA pyrimidine nucleotides came from dietary sources, whereas exogenous purine nucleotides could account for only 0-0.2% of the total pool of purine nucleotide tissue RNA.
NUCLEOT1DES IN INFANT NUTRITION
179
CONCLUSIONS
In summary, pyrimidine nucleotides are (a) present in disproportionately high quantity in human milk, (b) better preserved during storage in the breast and digestion in
the small intestine than are purine nucleotides, and (c) better absorbed and incorporated into tissue RNA than are purine nucleotides. These facts are consistent with the
work of Pizzini et al. (44), who showed that various beneficial effects of dietary nucleic acids may be reproduced by uracil alone.
A dietary source of nucleotides may be particularly important for infants whose
tissue needs are increased (preterm neonates, newborn infants with malnutrition or
chronic diarrhea, and so on), but what should be added and how much? Two facts
must be considered: first, the nucleotide content of infant formulas derived from
bovine milk is considerably lower than and different in composition from that of human milk (72); and second, infant formulas are generally developed and manufactured to be as similar to human milk as possible. Therefore, and particularly in the
United States, some companies have started to add nucleotides to their formulas to
reach the levels present in human milk, a practice that also was initiated in Japan in
1965 and in some European countries (for example, Spain, in 1983) (72). So far, no
deleterious effects have been reported. The European Commission's Scientific
Committee for Food published guidelines in 1991 and 1996 on nucleotide supplementation of infant formulas (73,74). These allow the use of the following nucleotides and their sodium salts: CMP, UMP, AMP, GMP, and IMP, at maximal concentrations of 2.5, 1.75, 1.5, 0.5, and 1.0 mg/100 kcal, respectively, for a total
maximum of 5 mg/100 kcal. The committee also stated that the total nucleotide concentration should be of the same order of magnitude as the free nucleotides in human
milk.
REFERENCES
1. Carver JD, Walker WA. The role of nucleotides in human nutrition. J Nutr Biochem 1995; 6: 58-72.
2. Rudolph FB. The biochemistry and physiology of nucleotides. J Nutr 1994; 124: 124-7S.
3. Uauy R. Dietary nucleotides and requirements in early life. In: Lebenthal E, ed. Textbook of gastroenterology and nutrition in infancy. New York: Raven Press, 1989: 265-80.
4. Quan R, Barness LA, Uauy R. Do infants need nucleotide supplemented formula for optimal nutrition? J Pediatr Gastroenterol Nutr 1990; 11: 429-37.
5. Uauy R, Quan R, Gil A. Role of nucleotides in intestinal development and repair: implications for infant nutrition. J Nutr 1994; 124: 1436-41S.
6. Jarvis SM. Characterisation of sodium-dependent nucleoside transport in rabbit intestinal brush-border membrane vesicles. Biochim Biophys Ada 1989; 979: 132-8.
7. Savaiano DA, Clifford AJ. Absorption, tissue incorporation and excretion of free purine bases in rats.
Nutr Rep Int 1978; 17: 551-6.
8. Sonoda T, Tatibana M. Metabolic fate of pyrimidines and purines ingested by mice. Biochim Biophys
Ada 1978; 521: 55-66.
9. Savaiano DA, Ho CY, Chu V, Clifford AJ. Metabolism of orally and intravenously administered
purine in rats. J Nutr 1980; 110: 1793-804.
10. Simmonds AH, Hatfield PJ, Cameron SJ, Jones AS, Cadenhead A. Metabolic studies of purine metabolism in the pig during the oral administration of guanine and allopurinol. Biochem Pharmacol
1973;22:2537-52.
11. Simmonds AH, Rising TJ, Cadenhead A, Hatfield PJ, Jones AS, Cameron SJ. Radioisotope studies of
purine metabolism during administration of guanine and allopurinol in the pig. Biochem Pharmacol
1973; 22: 2553-63.
180
NUCLEOTJDES IN INFANT NUTRITION
12. Boza JJ. Jahoor F, Reeds PJ. Ribonucleic acid nucleotides in maternal and fetal tissues derive almost
exclusively from synthesis de novo in pregnant mice. J Nutr 1996; 126: 1749-58.
13. He Y. Sanderson IR, Walker WA. Uptake, transport and metabolism of exogenous nucleosides in intestinal epithelial cell cultures. J Nutr 1994; 124: 1942-9.
14. Grimble GK. Essential and conditionally essential nutrients in clinical nutrition. Nutr Res Rev 1993;
6:97-119.
15. Boza JJ, Moennoz D, Bournot CE, et al. Role of glutamine on the de novo purine nucleotide synthesis in Caco-2 cells. Eur J Nutr 2000; 39: 3 8 ^ 6 .
16. Yamauchi K, Adjei AA, Ameho CK, et al. Nucleoside-nucleotide mixture increases bone marrow cell
number and small intestinal RNA content in protein-deficient mice after an acute bacterial infection.
Nutrition 1998; 14: 270-5.
17. Carver JD. Dietary nucleotides: effects on the immune and gastrointestinal systems. Ada Paediatr
1999; 88: 83-8.
18. Rudolph FB, Van Buren CT. The metabolic effects of enterally administered ribonucleic acids. Curr
Opin Clin Nutr Metab Care 1998; 1: 527-30.
19. Uauy R, Stringel G, Thomas R, Quan R. Effect of dietary nucleosides on growth and maturation of
the developing gut in the rat. J Pediatr Gastroenterol Nutr 1990; 10: 497-503.
20. Carver JD. Dietary nucleotides: cellular immune, intestinal and hepatic system effects. J Nutr 1994;
124: 144-8.
21. Ortega MA, Gil A, Sanchez-Pozo A. Maturation status of small intestine epithelium in rats deprived
of dietary nucleotides. Life Sci 1995; 56: 1623-30.
22. Quan R, Gil A, Uauy R. Effect of dietary nucleosides on intestinal growth and maturation after injury
from radiation. Pediatr Res 1991; 29: 111.
23. Nunez MC, Ayudarte MV, Morales D, Suarez MD, Gil A. Effect of dietary nucleotides on intestinal
repair in rats with experimental chronic diarrhoea. J Parenter Enteral Nutr 1990; 14: 598-604.
24. Ortega MC, Nunez MC, Gil A, Sanchez-Pozo A. Dietary nucleotides accelerate intestinal recovery after food deprivation in old rats. J Nutr 1995; 125: 1413-8.
25. Tsujinaka T, Kishibuchi M, Iijima S, Yano M, Monden M. Nucleotides and intestine. J Parenter
Enteral Nutr 1999; 23: S74-7.
26. Crosgrove M, Davies DP, Jenkins HR. Nucleotide supplementation and the growth of term small for
gestational age infants. Arch Dis Child Fetal Neonatal Ed 1996; 14: F122-5.
27. Sukumar P, Loo A, Magur E, Nandi J, Oler A, Levine RA. Dietary supplementation of nucleotides
and arginine promotes healing of small bowel ulcers in experimental ulcerative ileitis. Dig Dis Sci
1997; 42: 1530-6.
28. Sukumar P, Loo A, Adolphe R, Nandi J, Oler A, Levine RA. Dietary nucleotides augment dextran sulfate sodium-induced distal colitis in rats. J Nutr 1999; 129: 1377-81.
29. Iijima S, Tsujinaka T, Kido Y, et al. Intravenous administration of nucleosides and a nucleotide mixture diminishes intestinal mucosal atrophy induced by total parenteral nutrition. J Parenter Enteral
Nutr 1993; 17: 265-70.
30. Tsujinaka T, Iijima S, Kido Y, et al. Role of nucleosides and nucleotide mixture in intestinal mucosal
growth under total parenteral nutrition. Nutrition 1993; 9: 532-5.
31. Gil A, Corral E, Martinez-Valverde A, Molina JA. Effects of the addition of nucleotides to an adapted
milk formula on the microbial pattern of feces in at term newborn infants. J Clin Nutr Gastroenterol
1986; 1: 127-32.
32. Balmer SE, Hanvey LS, Wharton BA. Diet and faecal flora in the newborn: nucleotides. Arch Dis
Child 1994; 70: 137^tt).
33. Novak DA, Carver JD, Barness LA. Dietary nucleotides affect hepatic growth and composition in the
weanling mouse. J Parenter Enteral Nutr 1994; 18: 62-6.
34. Lopez-Navarro AT, Bueno JD, Gila A, Sanchez-Pozo A. Morphological changes in hepatocytes of
rats deprived of dietary nucleotides. Br J Nutr 1996; 26: 579-89.
35. Lopez-Navarro AT, Ortega MA, Peragon J, Gil A, Sanchez-Pozo A. Deprivation of dietary nucleotides decreases protein synthesis in the liver and the small intestine in rats. Gastroenterologv
1996; 110: 1760-9.
36. Ogoshi S, Iwasa M, Kitagawa S, et al. Effects of total parenteral nutrition with nucleoside and nucleotide mixture on D-galactosamine-induced liver injury in rats. J Parenter Enteral Nutr 1988; 12:
53-7.
37. Ogoshi S, Iwasa M, Yonezawa T, Tamiya T. Effect of nucleotide and nucleoside mixture on rats given
total parenteral nutrition after 70% hepatectomy. J Parenter Enteral Nutr 1985; 9: 339^12.
38. Fontana L, Moreira E, Torres MI, et al. Dietary nucleotides correct plasma and liver microsomal fatty
NUCLEOT1DES IN INFANT NUTRITION
39.
40.
41.
42.
43.
44.
45.
46.
47.
48.
49.
50.
51.
52.
53.
54.
55.
56.
57.
58.
59.
60.
61.
62.
63.
181
acid alterations in rats with liver cirrhosis induced by oral intake of thioacetamide. J Hepatol 1998;
28: 662-9.
Torres MI, Fernandez MI, Gil A, Rios A. Dietary nucleotides have cytoprotective properties in rat
liver damaged by thioacetamide. Life Sci 1998; 62: 13-22.
Barankiewicz J, Cohen A. Purine nucleotide metabolism in phytohemagglutinin-induced human T
lymphocytes. Arch Biochem Biophys 1987; 258: 167-75.
Rudolph FB, Kulkarni AD, Fanslow WC, Pizzini RP, Kumar S, Van Buren CT. Role of RNA as a dietary source of pyrimidines and purines in immune function. Nutrition 1990; 6: 45-52.
Van Buren CT, Kulkarni AD, Schandle CV. The influence of dietary nucleotides on cell mediated immunity. Transplantation 1983; 36: 350-2.
Van Buren CT, Kulkarni AD, Fanslow WC. Dietary nucleotides, a requirement for helper/inducer T
lymphocytes. Transplantation 1985; 40: 694-7.
Pizzini RP, Kumar S, Kulkarni AD, Rudolph FB, Van Buren CT. Dietary nucleotides reverse malnutrition and starvation-induced immunosuppression. Arch Surg 1990; 125: 86-90.
Kulkarni AD, Fanslow WC, Rudolph FB, Van Buren CT. Modulation of delayed hypersensitivity in
mice by dietary nucleotide restriction. Transplantation 1987; 44: 847-9.
Yamauchi Y, Adjei AA, Ameho CK, et al. A nucleotide-nucleoside mixture and its components increase lymphoproliferative and delayed hypersensitivity responses in mice. J Nutr 1996; 126: 1571 -7.
Carver JD, Cox WI, Barness LA. Dietary nucleotide effects upon murine natural killer cell activity
and macrophage activation. J Parenter Enteral Nutr 1990; 14: 18-22.
Perignon JL, Bories DM, Houllier AM, Thuillier L, Cartier PH. Metabolism of pyrimidine bases and
nucleosides by pyrimidine-nucleoside phosphorylases in cultured human lymphoid cells. Biochim
Biophys Acta 1987; 928: 130-6.
Fanslow WC, Kulkarni AD, Van Buren CT, Rudolph FB. Effect of nucleotide restriction and supplementation on resistance to experimental candidiasis. J Parenter Enteral Nutr 1988; 12: 49-52.
Adjei AA, Takamine F, Yokoyama H, et al. The effects of oral RNA and intraperitoneal nucleosidenucleotide administration on methicillin-resistant Staphylococcus aureus infection in mice. J
Parenter Enteral Nutr 1993; 17: 148-52.
Adjei AA, Yamauchi K, Chan YC, Konishi M, Yamamoto S. Comparative effects of dietary nucleoside-nucleotide mixture and its components on endotoxin induced bacterial translocation and small intestinal injury in protein deficient mice. Gut 1996; 38: 531-7.
Adjei AA, Jones JT, Enriquez FJ, Yamamoto S. Dietary nucleosides and nucleotides reduce
Cryptosporidium parvum infection in dexamethasone immunosuppressed adult mice. Exp Parasitol
1999; 92: 199-208.
Adjei AA, Morioka T, Ameho CK, et al. Nucleoside-nucleotide free diet protects rat colonic mucosa
from damage induced by trinitrobenzene sulphonic acid. Gut 1996; 39: 428-33.
Jyonouchi H, Sun S. An orally supplemented mononucleotide mixture prevents the decrease in T-celldependent humoral immunity in C57BL/6 mice fed a nucleotide-free diet. J Nutr 1996; 126: 1586-93.
Jyonouchi H, Hill RJ, Voss RM, Ishii E. Immunomodulating actions of RNA and nucleotides on
murine lymphocytes in vitro: augmentation of antibody production to T-dependent antigens on expansion of T-helper cells. J Nutr Immunol 1993; 2: 5-24.
Jyonouchi H, Zhang-Shanbhag L, Georgieff M, Tomita Y. Immunomodulating actions of nucleotides:
enhancement of immunoglobulin production by human cord blood lymphocytes. Pediatr Res 1993;
34:565-71.
Carver JD, Pimentel B, Cox WI, Barness LA. Dietary nucleotide effects upon immune function in infants. Pediatrics 1991; 88: 359-63.
Pickering LK, Granoff DM, Erickson J, Masor ML, Hilty MD. Dietary modulation of the immune system by human milk and infant formula containing human milk levels of nucleotides. Pediatrics 1998;
101:242-9.
Martinez-Augustin O, Boza JJ, Del Pino JI, Lucena J, Martinez-Valverde A, Gil A. Dietary nucleotides might influence the humoral immune response against cow's milk proteins in preterm
neonates. Biol Neonate 1997; 71: 215-23.
Martinez-Augustin O, Boza JJ, Navarro J, Martinez-Valverde A, Araya M, Gil A. Dietary nucleotides
may influence the humoral immunity in immunocompromised children. Nutrition 1997; 13: 465-9.
Brunser O, Espinoza J, Araya M, Cruchet S, Gil A. Effect of dietary nucleotide supplementation on
diarrhoeal disease in infants. Acta Paediatr 1994; 83: 188-91.
Gil A, Sanchez de Medina F. Acid-soluble nucleotides of human milk at different stages of lactation.
J Dairy Res 1981; 49: 301-7.
Janas LM, Picciano MF. The nucleotide profile of human milk. Pediatr Res 1982; 16: 659-62.
/ 82
NUCLEOTIDES IN INFANT NUTRITION
64. Durschlag RP, Robinson JL. Species specificity in the metabolic consequences of orotic acid consumption. J Nutr 1980; 110: 822-8.
65. Harden KK, Robinson JL. Hypocholestemia induced by orotic acid: dietary effects and species specificity. J Nutr 1984; 114:411-21.
66. Donovan, Lonnerdal B. Non-protein nitrogen and true protein in infant formulas. Ada Paediatr Scand
1989; 78: 497-504.
67. Carlson SE. Human milk non-protein nitrogen: occurrence and possible functions. Adv Pediatr 1985;
32: 43-70.
68. Hamosh M. Should infant formulas be supplemented with bioactive components and conditionally essential nutrients present in human milk? J Nutr 1997; 127: 9 7 1 ^ S .
69. Leach JL, Baxter JH, Molitor BE, Ramstack MB, Masor ML. Total potentially available nucleosides
of human milk by stage of lactation. Am J Clin Nutr 1995; 61: 1224-30.
70. Thorell L, Sjoberg LB, Hernell O. Nucleotides in human milk: sources and metabolism by the newborn infant. Pediatr Res 1996; 40: 845-52.
71. Reeds PJ, Berthold HK, Boza JJ, et al. Integration of amino acid and carbon intermediary metabolism:
studies with uniformly labelled tracers and mass isotopomer analysis. Eur J Pediatr 1997; 156: S5O-8.
72. Yu VYH. The role of dietary nucleotides in neonatal and infant nutrition. Singapore MedJ 1998; 39:
145-50.
73. Scientific Committee for Food. Second Addendum to the report concerning the essential requirements
of infants formulae and follow-up milks based on cow's milk proteins: Luxembourg: European
Commission of the European Communities (Directive 91/32 I/EEC), 28th series, 1991: 30-5.
74. Scientific Committee for Food. Commission Directive amending Directive 91/321/EEC on infant formulae and follow-up formulae. Luxembourg: European Commission of the European Communities
(Directive 96/4/EC), 1996: 7.
DISCUSSION
Dr. Moro: Do you have an idea of the effects of temperature on the nucleotides present in
human milk? I mean pasteurization or freezing of the milk.
Dr. Boza: I do not know about human milk, but I can tell you what happens to nucleotides
added to cow's-milk formula submitted to UHT treatment. They are partially converted into nucleosides, but they are still absorbable, and this is actually the main form in which nucleotides
are absorbed. They do not appear to be converted into uric acid or other nonabsorbable forms.
Dr. Hernell: You showed that there is an enhanced antibody response to (3-lactoglobulin.
Do you interpret this as being an indication of a more mature immune system? If so, could that
not actually be a risk factor for intolerance?
Dr. Boza: I agree entirely with you. There could be a risk to oral tolerance of this kind of
protein. Unfortunately there are no further studies on this subject, and the investigators did not
follow up the infants, so we do not know whether or not they developed increased allergy to
cow's-milk proteins.
Dr. Hernell: You also mentioned that the formula had a nucleotide composition similar to
that of human milk. One of the points we made in our article (1) is the uncertainty of humanmilk composition—it depends on how you handle the milk after it has been expressed from the
breast up to the time of analysis, because of inevitable degradation.
Dr. Boza: Again I agree entirely with you. The method of collecting the samples and their
subsequent storage is very important in determining the actual mononucleotide content of human milk. You have shown that degradation occurs because of the presence of enzymes in human milk that can degrade all the way up to uric acid, especially purine nucleotides, so the
most important thing is to freeze the milk rapidly after collection.
Dr. Raiha: Many of the effects you showed in the articles you referred to may be especially
beneficial in preterm infants. Do you know whether there are more nucleotides in preterm milk
than in mature milk?
NUCLEOTIDES IN INFANT NUTRITION
183
Dr. Boza: I do not know. I have no data on the content of nucleotides in preterm milk. I
agree with you that the benefits of dietary nucleotides are more likely to affect preterm infants
than, say, 1-year-old children.
Dr. Read: Could you comment a little more on the studies relating to the gut. Do you see a
proliferation of normal gut as opposed to damaged gut, and if so, is the growth balanced or is
crypt proliferation increased selectively, which might indicate some danger of cancer?
Dr. Boza: The results we obtained were much more pronounced when there was gut injury—a situation in which there is an increased rate of cell proliferation. We found in healthy
growing rats that there was an increase in cell proliferation at the level of the crypts.
Dr. Endres: A while ago at an ESPGAN meeting, the Pickering group presented data similar to yours, showing increased vaccination titers after ingesting formula that had been supplemented with nucleotides. In the discussion it was stated that the soy formula they used had
a natural content of nucleotides. Is it true that soy proteins contain nucleotides?
Dr. Boza: The formula that Pickering was using in that study contained added nucleotides.
I do not know the nucleotide content of soy protein in the raw state.
Dr. Bachmann: We usually associate immunologic effects more with purines than with
pyrimidines. We think of adenosine deaminase deficiency or purine nucleoside phosphorylase
deficiency, but these are to do with the purine side, whereas you seem to advocate the pyrimidine side more. Maybe purines are low because the enterocytes that need to regenerate themselves reuse purines better via the salvage pathway. I am somewhat confused about your article. On the one hand, you raise concerns about purines and pyrimidines, whereas on the other
hand, you emphasize that purines may be important with respect to T and B lymphocytes. We
know from work in the 1980s by Baker and others that the oxyglucose moiety in nucleosides
is more important in influencing the immune response than are the normal hexoses. So my
question is, do you have any idea if we have to deal with deoxynucleotides?
Dr. Boza: If one is considering de novo synthesis, it does not matter whether deoxyglucose
is used because the purine ring and the sugar ring are resynthesized at the same time. From the
studies I have looked at, it seems that there is almost no salvage of purine nucleotides. Not only
are they almost entirely catabolyzed to uric acid, but they also are tightly controlled and regulated because they can exert important effects on the systemic circulation and because they regulate many metabolic pathways. A large increase in the concentration of this nucleotide could
have major consequences in some pathways.
Dr. Vigi: It puzzles me that these small quantities of substances that are produced normally
in the body and that represent only a fraction of the total metabolism of nucleotides can exert
such important effects. You cannot explain all these on the supply theory because all the effects appear to be obtainable with different added nucleotides—for example, the effect on diarrhea in poor populations, the effect on the response to immunization, and so on. We even
hear talk about nucleotides having an effect on lipid metabolism, so everything could be included! Might it not be better to concentrate on more proven effects? I would like a general
comment. This is not a question but a request for an opinion.
Dr. Boza: My opinion about nucleotide supplementation is that in healthy newborn infants,
with the quantities we are adding to formulas, we will hardly see any effects at all. But in infants receiving a limited protein intake, or in those prone to developing infections because of
their environment, or with gut injury or malabsorption syndromes, then the small quantities we
have been discussing may make a real difference. I am not speaking about the quantity that we
are giving, only about the quantity the enterocytes are not catabolizing. We need to focus on
the role of the enterocyte in the salvage of purines and pyrimidines in the diet. That is the most
important point.
184
NUCLEOTIDES IN INFANT NUTRITION
Dr. Vigi: So you are not in favor of additional nucleotides in starting formulas for normal
infants?
Dr. Boza: I am not saying that. I do not think there are good enough studies as yet showing
the beneficial effects. We need specific controlled trials to show whether added nucleotides
may spare amino acids normally used in nucleotide synthesis, so they can be used for other
purposes.
Dr. Bohles: There is a lot of orotate in cow's milk. Is there any orotate in human milk?
Dr. Boza: There is no orotate in human milk. Orotate is one of the precursors of pyrimidine
synthesis and is present in cow's milk. It has been shown in rats that it can cause hepatic fatty
acid accumulation, which is unique to the rat.
REFERENCES
1. Thorell L, Sjoberg LB, Hernell O. Nucleotides in human milk: sources and metabolism by the newborn
infant. Pediatr Res 1996;40:845-52.
