FLAVOUR ADDITIVES

Abstract

The present invention relates to the use of one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones for increasing the palatability of a foodstuff to a companion animal. The invention also relates to a pet foodstuff or supplement comprising one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones, and also to a method of increasing the palatability of a foodstuff to a companion animal.

Description

The present invention relates to the use of one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones for increasing the palatability of a foodstuff to a companion animal. The invention also relates to a pet foodstuff or supplement comprising one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones, and also to a method of increasing the palatability of a foodstuff to a companion animal.

It is well known that many feline and canine companion animals are fussy with their food. An animal will often refuse to eat a foodstuff that it has been accepting over some time, or refuse to eat any more than a minimal amount of a foodstuff. Part of this phenomenon can be driven by subtle changes in the sensory profile of the raw materials. These changes might not be perceived by the human consumer, but due to a difference in the olfactory and gustatory systems, feline and canine companion animals may well perceive these differences. These sensory differences can be due to natural variation of the raw materials used or when materials are in short supply and have to be substituted with alternatives. This can be very frustrating for the owner and can result in the owner perceiving that the animal is unhappy and not enjoying its food. An animal may also fail to ingest its required amount of essential nutrients if not consuming an adequate amount of food available to it. Therefore, it can clearly be seen that there exists a need for a way to encourage companion animals to eat the foodstuff with which it is provided. Many solutions have been suggested to overcome this problem. Most commercially available pet foods are provided in a range of different flavours and/or textures. However, the companion animal owner will know that often a companion animal will suddenly, for no clear reason, refuse the flavour that the owner perceives to be its most preferred. Much research has been carried out on the flavour preferences of companion animals, by offering them a choice of different foodstuffs. The present inventors have taken this research further by studying the key taste receptor in cat, the umami receptor (umami flavour is also referred to as savoury or meat flavour) and identifying the associated taste mechanisms. They have looked at a range of compounds, volatile and non-volatile, that are found in naturally occurring foodstuffs and established the interactions of these compounds and therefore developed a combination for optimal taste. Of particular interest and importance has been a focus on compounds that interact with and are perceived via the umami and other receptors.

Surprisingly, the inventors have found that companion animals show a strong and consistent preference for certain combinations of compounds, whether presented to the animals in water, a gel or in a model foodstuff. The present invention therefore relates to a use of a combination of compounds that is highly desirable to a companion animal for increasing palatability of a foodstuff to a companion animal. The companion animal is preferably a mammalian companion animal.

When a companion animal eats its recommended amount of (main meal) foodstuff each day, the animal will receive its required level of vitamins and minerals, and thus is highly likely to remain healthy and happy. Furthermore, the owner is satisfied that the animal is eating well. The inventors have identified certain volatile and non-volatile compounds that are present in natural products that particularly appeal to companion animals in combination. Non-volatile compounds relate to taste, (i.e. they are detected on the tongue); volatile compounds relate to aroma, and are compounds that affect the smell of the food, (i.e. compounds detected in the nose); and some compounds fall within both categories. The combination of both taste and aroma give the food its flavour. Flavour, as used herein, therefore encompasses both the taste and aroma of a foodstuff

The invention, therefore, provides as a first aspect the use of one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones for increasing the palatability of a foodstuff to a companion animal and, therefore, for use in ensuring an adequate intake of food stuff by a companion animal. The amino acid may be selected from the group consisting of proline, threonine or valine.

The nucleotide may be selected from the group consisting of adenosine monophosphate (AMP), guanosine monophosphate (GMP), inosine monophosphate (IMP), uridine monophosphate (UMP), cytidine monophosphate (CMP), xanthosine monophosphate (XMP) or a mixture of two or more thereof. The nucleotide may be AMP, GMP, or IMP or a mixture thereof. The nucleotide may be GMP alone, or IMP alone, or a mixture of IMP and GMP. The nucleotide may be a mixture of GMP and IMP from about 1% to about 99% of GMP and of from about 1% to about 99% of IMP, more preferably, of from about 20% to about 80% of GMP and of from about 20% to about 80% of IMP or a mixture of about 50% GMP and about 50% IMP.

The amino acid is selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine or a mixture of 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 thereof. Suitably, the amino acid may be selected from the group consisting of proline, threonine and valine. The amino acid is preferably in the amino acid form.

The furanone is suitably as set out in formula I or formula II, below, optionally substituted by hydroxyl, C_1-6 alkyl, C_1-6 alkoxy.

Each R₁ and R₂ are independently selected from hydrogen or C_1-6 alkyl, preferably hydrogen, methyl or ethyl;

R₃ is hydrogen, hydroxyl or C_1-6 alkyl, preferably methyl;

R₄ is hydrogen, hydroxyl or C_1-6 alkyl, preferably hydroxyl;

R₅ is hydrogen, hydroxyl, C_1-6 alkyl, C_1-6 alkoxy, 5 or 6 membered saturated heterocycle or —OC(O)R₇, preferably hydroxyl, —OCH₃, —OCH₂CH₃, —OC(O)CH₃, methyl or pyrrolidine;

R₆ is hydrogen or C_1-6 alkyl, preferably hydrogen or methyl;

R₇ is C_1-6 alkyl, preferably methyl.

The furanone may be selected from the group consisting of the furanones set out in Table 1, or a mixture of 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 or 12 thereof. Suitably, the furanone is furaneol, homofuraneol, sotolon, norfuraneol, abhexon, mesifuranone, dimethoxyfuranone, or norfuraneol, as defined in Table 1. Alternatively, the furanone may be selected from the group consisting of furaneol, sotolon and abhexon, as defined herein in Table 1.

TABLE 1
Key Furanones           Additional Furanones
Furaneol                Acetoxydimethylfuranone
(2R)-(+)-Homofuraneol I Dimethylethoxyfuranone
Sotolon                 DMPF
Norfuraneol             (2R)-(+)-Homofuraneol II
Abhexon                 (2S)-(−)-Homofuraneol I
Dimethylmethoxyfuranone (2S)-(−)-Homofuraneol II
(Mesifuranone)

Optionally, the invention may also include the use of a pyrophosphate, such as tetra potassium pyrophosphate or a disodium pyrophosphate. Polyphosphates may be included in the composition also, such as sodium tripolyphosphate. The pyrophosphates and/or polyphosphates may be present in the composition at a concentration of 1 mM or above. Suitably, the concentration of pyrophosphate and/or polyphosphate may be 5 mM, 10 mM, 15 mM, 20 mM, 25 mM, 30 mM, 40 mM, 50 mM, 100 mM or 500 mM.

The invention includes a composition comprising one or more nucleotides, one or more amino acids and one or more furanones, as herein defined, for use in increasing the palatability of a foodstuff to a companion animal. The composition may also comprise a pyrophosphate and/or polyphosphate as herein defined.

The one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine may be present (individually or as a combination) in an amount of less than 1M, 1 mM to 1M, 250 mM to 1M, 5 mM to 500 mM, 10 mM to 100 mM, 10 mM to 50 mM or 20 mM to 50 mM. The amount of amino acid may be less than 200 mM, less than 100 mM, less than 20 mM or less than 10 mM. The amino acid(s) may be present in an amount of 25 mM.

The one or more nucleotides may be present (individually or as a combination) in an amount of less than 100 mM, 0.1 mM to 100 mM, 0.5 mM to 50 mM, 1 mM to 20 mM or 5 mM to 10 mM. The nucleotide may be present in an amount of greater than 1 mM or greater than 2.5 mM. The nucleotide may be present in an amount of less than 50 mM, less than 20 mM or less than 10 mM. Most preferably, the one or more nucleotides may be present in an amount of 1 mM to 100 mM, such as 5 mM, or 2 mM. The nucleotide(s) may be present in an amount of 5 mM.

The one or more furanones may be present (individually or as a combination) at a concentration of greater than 0.005 ppm, 0.001 ppm to 40 ppm, 0.005 ppm to 20 ppm, 0.001 ppm to 5 ppm, 1 ppm to 10 ppm or 2 ppm to 5 ppm. The furanone(s) may be present in an amount of less than 40 ppm. The furanone(s) may be present in an amount of 4 ppm.

The one or more nucleotides, the one or more amino acids and the one or more furanones for use in the invention are in addition to those found naturally in meat, vegetable or dairy products that may form part of a food stuff. The nucleotide(s) amino acid(s) and furanone(s) may be added to a pet food during or after manufacture. The nucleotide(s), amino acid(s) and furanone(s) are added in order to enhance or optimise the flavour profile of the basic meat (or other macronutrient) ingredients of the pet food.

The companion animal is preferably a feline animal (cat), or a canine animal (dog) although it may also be a guinea pig, a rabbit, bird or a horse.

The invention also provides as a second aspect a pet foodstuff comprising one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine, and one or more furanones. The foodstuff may be packaged, wherein the packaging carries written or graphic information indicating that the pet foodstuff is meant to be consumed by a cat or a dog, or a guinea pig, a rabbit, a bird or a horse. The suitable and preferred features of the first aspect also apply to the second aspect, mutatis mutandis.

The combination of nucleotide, amino acid and furanone may be any set out in Table 2. The mixture of GMP to IMP may be of from 1 to 99:99 to 1, preferably from 20 to 80:80 to 20, or about 50:50 in all combinations including GMP and IMP in Table 2, provided of course that the total amount of the combination is 100%. The preferred levels of proline, threonine and/or valine and GMP, IMP, GMP/IMP and AMP are as stated above.

	TABLE 2
	Nucleotides	Amino Acids	Furanones
	GMP from about 1% to	Proline	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Proline	Furaneol
	GMP	Proline	Furaneol
	AMP	Proline	Furaneol
	GMP from about 1% to	Proline	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Proline	Norfuraneol
	GMP	Proline	Norfuraneol
	AMP	Proline	Norfuraneol
	GMP from about 1% to	Proline	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Proline	Homofuraneol
	GMP	Proline	Homofuraneol
	AMP	Proline	Homofuraneol
	GMP from about 1% to	Proline	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Proline	Abhexon
	GMP	Proline	Abhexon
	AMP	Proline	Abhexon
	GMP from about 1% to	Proline	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Proline	Mesifuranone
	GMP	Proline	Mesifuranone
	AMP	Proline	Mesifuranone
	GMP from about 1% to	Proline	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Proline	Sotolon
	GMP	Proline	Sotolon
	AMP	Proline	Sotolon
	GMP from about 1% to	Glutamic acid	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamic acid	Furaneol
	GMP	Glutamic acid	Furaneol
	AMP	Glutamic acid	Furaneol
	GMP from about 1% to	Glutamic acid	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamic acid	Norfuraneol
	GMP	Glutamic acid	Norfuraneol
	AMP	Glutamic acid	Norfuraneol
	GMP from about 1% to	Glutamic acid	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamic acid	Homofuraneol
	GMP	Glutamic acid	Homofuraneol
	AMP	Glutamic acid	Homofuraneol
	GMP from about 1% to	Glutamic acid	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamic acid	Abhexon
	GMP	Glutamic acid	Abhexon
	AMP	Glutamic acid	Abhexon
	GMP from about 1% to	Glutamic acid	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamic acid	Mesifuranone
	GMP	Glutamic acid	Mesifuranone
	AMP	Glutamic acid	Mesifuranone
	GMP from about 1% to	Glutamic acid	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamic acid	Sotolon
	GMP	Glutamic acid	Sotolon
	AMP	Glutamic acid	Sotolon
	GMP from about 1% to	Aspartic acid	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Aspartic acid	Furaneol
	GMP	Aspartic acid	Furaneol
	AMP	Aspartic acid	Furaneol
	GMP from about 1% to	Aspartic acid	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Aspartic acid	Norfuraneol
	GMP	Aspartic acid	Norfuraneol
	AMP	Aspartic acid	Norfuraneol
	GMP from about 1% to	Aspartic acid	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Aspartic acid	Homofuraneol
	GMP	Aspartic acid	Homofuraneol
	AMP	Aspartic acid	Homofuraneol
	GMP from about 1% to	Aspartic acid	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Aspartic acid	Abhexon
	GMP	Aspartic acid	Abhexon
	AMP	Aspartic acid	Abhexon
	GMP from about 1% to	Aspartic acid	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Aspartic acid	Mesifuranone
	GMP	Aspartic acid	Mesifuranone
	AMP	Aspartic acid	Mesifuranone
	GMP from about 1% to	Aspartic acid	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Aspartic acid	Sotolon
	GMP	Aspartic acid	Sotolon
	AMP	Aspartic acid	Sotolon
	GMP from about 1% to	Arginine	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Arginine	Furaneol
	GMP	Arginine	Furaneol
	AMP	Arginine	Furaneol
	GMP from about 1% to	Arginine	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Arginine	Norfuraneol
	GMP	Arginine	Norfuraneol
	AMP	Arginine	Norfuraneol
	GMP from about 1% to	Arginine	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Arginine	Homofuraneol
	GMP	Arginine	Homofuraneol
	AMP	Arginine	Homofuraneol
	GMP from about 1% to	Arginine	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Arginine	Abhexon
	GMP	Arginine	Abhexon
	AMP	Arginine	Abhexon
	GMP from about 1% to	Arginine	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Arginine	Mesifuranone
	GMP	Arginine	Mesifuranone
	AMP	Arginine	Mesifuranone
	GMP from about 1% to	Arginine	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Arginine	Sotolon
	GMP	Arginine	Sotolon
	AMP	Arginine	Sotolon
	GMP from about 1% to	Cystine	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Cystine	Furaneol
	GMP	Cystine	Furaneol
	AMP	Cystine	Furaneol
	GMP from about 1% to	Cystine	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Cystine	Norfuraneol
	GMP	Cystine	Norfuraneol
	AMP	Cystine	Norfuraneol
	GMP from about 1% to	Cystine	Homofuraneol
	about 100% and IMP from
	about 1% to about 99%
	IMP	Cystine	Homofuraneol
	GMP	Cystine	Homofuraneol
	AMP	Cystine	Homofuraneol
	GMP from about 1% to	Cystine	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Cystine	Abhexon
	GMP	Cystine	Abhexon
	AMP	Cystine	Abhexon
	GMP from about 1% to	Cystine	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Cystine	Mesifuranone
	GMP	Cystine	Mesifuranone
	AMP	Cystine	Mesifuranone
	GMP from about 1% to	Cystine	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Cystine	Sotolon
	GMP	Cystine	Sotolon
	AMP	Cystine	Sotolon
	GMP from about 1% to	Glutamine	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamine	Furaneol
	GMP	Glutamine	Furaneol
	AMP	Glutamine	Furaneol
	GMP from about 1% to	Glutamine	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamine	Norfuraneol
	GMP	Glutamine	Norfuraneol
	AMP	Glutamine	Norfuraneol
	GMP from about 1% to	Glutamine	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamine	Homofuraneol
	GMP	Glutamine	Homofuraneol
	AMP	Glutamine	Homofuraneol
	GMP from about 1% to	Glutamine	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamine	Abhexon
	GMP	Glutamine	Abhexon
	AMP	Glutamine	Abhexon
	GMP from about 1% to	Glutamine	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamine	Mesifuranone
	GMP	Glutamine	Mesifuranone
	AMP	Glutamine	Mesifuranone
	GMP from about 1% to	Glutamine	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Glutamine	Sotolon
	GMP	Glutamine	Sotolon
	AMP	Glutamine	Sotolon
	GMP from about 1% to	Isoleucine	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Isoleucine	Furaneol
	GMP	Isoleucine	Furaneol
	AMP	Isoleucine	Furaneol
	GMP from about 1% to	Isoleucine	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Isoleucine	Norfuraneol
	GMP	Isoleucine	Norfuraneol
	AMP	Isoleucine	Norfuraneol
	GMP from about 1% to	Isoleucine	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Isoleucine	Homofuraneol
	GMP	Isoleucine	Homofuraneol
	AMP	Isoleucine	Homofuraneol
	GMP from about 1% to	Isoleucine	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Isoleucine	Abhexon
	GMP	Isoleucine	Abhexon
	AMP	Isoleucine	Abhexon
	GMP from about 1% to	Isoleucine	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Isoleucine	Mesifuranone
	GMP	Isoleucine	Mesifuranone
	AMP	Isoleucine	Mesifuranone
	GMP from about 1% to	Isoleucine	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Isoleucine	Sotolon
	GMP	Isoleucine	Sotolon
	AMP	Isoleucine	Sotolon
	GMP from about 1% to	Lysine	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Lysine	Furaneol
	GMP	Lysine	Furaneol
	AMP	Lysine	Furaneol
	GMP from about 1% to	Lysine	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Lysine	Norfuraneol
	GMP	Lysine	Norfuraneol
	AMP	Lysine	Norfuraneol
	GMP from about 1% to	Lysine	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Lysine	Homofuraneol
	GMP	Lysine	Homofuraneol
	AMP	Lysine	Homofuraneol
	GMP from about 1% to	Lysine	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Lysine	Abhexon
	GMP	Lysine	Abhexon
	AMP	Lysine	Abhexon
	GMP from about 1% to	Lysine	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Lysine	Mesifuranone
	GMP	Lysine	Mesifuranone
	AMP	Lysine	Mesifuranone
	GMP from about 1% to	Lysine	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Lysine	Sotolon
	GMP	Lysine	Sotolon
	AMP	Lysine	Sotolon
	GMP from about 1% to	Threonine	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Threonine	Furaneol
	GMP	Threonine	Furaneol
	AMP	Threonine	Furaneol
	GMP from about 1% to	Threonine	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Threonine	Norfuraneol
	GMP	Threonine	Norfuraneol
	AMP	Threonine	Norfuraneol
	GMP from about 1% to	Threonine	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Threonine	Homofuraneol
	GMP	Threonine	Homofuraneol
	AMP	Threonine	Homofuraneol
	GMP from about 1% to	Threonine	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Threonine	Abhexon
	GMP	Threonine	Abhexon
	AMP	Threonine	Abhexon
	GMP from about 1% to	Threonine	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Threonine	Mesifuranone
	GMP	Threonine	Mesifuranone
	AMP	Threonine	Mesifuranone
	GMP from about 1% to	Threonine	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Threonine	Sotolon
	GMP	Threonine	Sotolon
	AMP	Threonine	Sotolon
	GMP from about 1% to	Valine	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Valine	Furaneol
	GMP	Valine	Furaneol
	AMP	Valine	Furaneol
	GMP from about 1% to	Valine	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Valine	Norfuraneol
	GMP	Valine	Norfuraneol
	AMP	Valine	Norfuraneol
	GMP from about 1% to	Valine	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Valine	Homofuraneol
	GMP	Valine	Homofuraneol
	AMP	Valine	Homofuraneol
	GMP from about 1% to	Valine	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Valine	Abhexon
	GMP	Valine	Abhexon
	AMP	Valine	Abhexon
	GMP from about 1% to	Valine	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Valine	Mesifuranone
	GMP	Valine	Mesifuranone
	AMP	Valine	Mesifuranone
	GMP from about 1% to	Valine	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Valine	Sotolon
	GMP	Valine	Sotolon
	AMP	Valine	Sotolon
	GMP from about 1% to	Ornithine	Furaneol
	about 100% and IMP from
	about 1% to 100%
	IMP	Ornithine	Furaneol
	GMP	Ornithine	Furaneol
	AMP	Ornithine	Furaneol
	GMP from about 1% to	Ornithine	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Ornithine	Norfuraneol
	GMP	Ornithine	Norfuraneol
	AMP	Ornithine	Norfuraneol
	GMP from about 1% to	Ornithine	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Ornithine	Homofuraneol
	GMP	Ornithine	Homofuraneol
	AMP	Ornithine	Homofuraneol
	GMP from about 1% to	Ornithine	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Ornithine	Abhexon
	GMP	Ornithine	Abhexon
	AMP	Ornithine	Abhexon
	GMP from about 1% to	Ornithine	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Ornithine	Mesifuranone
	GMP	Ornithine	Mesifuranone
	AMP	Ornithine	Mesifuranone
	GMP from about 1% to	Ornithine	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Ornithine	Sotolon
	GMP	Ornithine	Sotolon
	AMP	Ornithine	Sotolon
	UMP	Proline	Furaneol
	XMP	Proline	Furaneol
	CMP	Proline	Furaneol
	UMP	Proline	Norfuraneol
	XMP	Proline	Norfuraneol
	CMP	Proline	Norfuraneol
	UMP	Proline	Homofuraneol
	XMP	Proline	Homofuraneol
	CMP	Proline	Homofuraneol
	UMP	Proline	Abhexon
	XMP	Proline	Abhexon
	CMP	Proline	Abhexon
	UMP	Proline	Mesifuranone
	XMP	Proline	Mesifuranone
	CMP	Proline	Mesifuranone
	UMP	Proline	Sotolon
	XMP	Proline	Sotolon
	CMP	Proline	Sotolon
	UMP	Glutamic acid	Furaneol
	XMP	Glutamic acid	Furaneol
	CMP	Glutamic acid	Furaneol
	UMP	Glutamic acid	Norfuraneol
	XMP	Glutamic acid	Norfuraneol
	CMP	Glutamic acid	Norfuraneol
	UMP	Glutamic acid	Homofuraneol
	XMP	Glutamic acid	Homofuraneol
	CMP	Glutamic acid	Homofuraneol
	UMP	Glutamic acid	Abhexon
	XMP	Glutamic acid	Abhexon
	CMP	Glutamic acid	Abhexon
	UMP	Glutamic acid	Mesifuranone
	XMP	Glutamic acid	Mesifuranone
	CMP	Glutamic acid	Mesifuranone
	UMP	Glutamic acid	Sotolon
	XMP	Glutamic acid	Sotolon
	CMP	Glutamic acid	Sotolon
	UMP	Aspartic acid	Furaneol
	XMP	Aspartic acid	Furaneol
	CMP	Aspartic acid	Furaneol
	UMP	Aspartic acid	Norfuraneol
	XMP	Aspartic acid	Norfuraneol
	CMP	Aspartic acid	Norfuraneol
	UMP	Aspartic acid	Homofuraneol
	XMP	Aspartic acid	Homofuraneol
	CMP	Aspartic acid	Homofuraneol
	UMP	Aspartic acid	Abhexon
	XMP	Aspartic acid	Abhexon
	CMP	Aspartic acid	Abhexon
	UMP	Aspartic acid	Mesifuranone
	XMP	Aspartic acid	Mesifuranone
	CMP	Aspartic acid	Mesifuranone
	UMP	Aspartic acid	Sotolon
	XMP	Aspartic acid	Sotolon
	CMP	Aspartic acid	Sotolon
	UMP	Arginine	Furaneol
	XMP	Arginine	Furaneol
	CMP	Arginine	Furaneol
	UMP	Arginine	Norfuraneol
	XMP	Arginine	Norfuraneol
	CMP	Arginine	Norfuraneol
	UMP	Arginine	Homofuraneol
	XMP	Arginine	Homofuraneol
	CMP	Arginine	Homofuraneol
	UMP	Arginine	Abhexon
	XMP	Arginine	Abhexon
	CMP	Arginine	Abhexon
	UMP	Arginine	Mesifuranone
	XMP	Arginine	Mesifuranone
	CMP	Arginine	Mesifuranone
	UMP	Arginine	Sotolon
	XMP	Arginine	Sotolon
	CMP	Arginine	Sotolon
	UMP	Cystine	Furaneol
	XMP	Cystine	Furaneol
	CMP	Cystine	Furaneol
	UMP	Cystine	Norfuraneol
	XMP	Cystine	Norfuraneol
	CMP	Cystine	Norfuraneol
	UMP	Cystine	Homofuraneol
	XMP	Cystine	Homofuraneol
	CMP	Cystine	Homofuraneol
	UMP	Cystine	Abhexon
	XMP	Cystine	Abhexon
	CMP	Cystine	Abhexon
	UMP	Cystine	Mesifuranone
	XMP	Cystine	Mesifuranone
	CMP	Cystine	Mesifuranone
	UMP	Cystine	Sotolon
	XMP	Cystine	Sotolon
	CMP	Cystine	Sotolon
	UMP	Glutamine	Furaneol
	XMP	Glutamine	Furaneol
	CMP	Glutamine	Furaneol
	UMP	Glutamine	Norfuraneol
	XMP	Glutamine	Norfuraneol
	CMP	Glutamine	Norfuraneol
	UMP	Glutamine	Homofuraneol
	XMP	Glutamine	Homofuraneol
	CMP	Glutamine	Homofuraneol
	UMP	Glutamine	Abhexon
	XMP	Glutamine	Abhexon
	CMP	Glutamine	Abhexon
	UMP	Glutamine	Mesifuranone
	XMP	Glutamine	Mesifuranone
	CMP	Glutamine	Mesifuranone
	UMP	Glutamine	Sotolon
	XMP	Glutamine	Sotolon
	CMP	Glutamine	Sotolon
	UMP	Isoleucine	Furaneol
	XMP	Isoleucine	Furaneol
	CMP	Isoleucine	Furaneol
	UMP	Isoleucine	Norfuraneol
	XMP	Isoleucine	Norfuraneol
	CMP	Isoleucine	Norfuraneol
	UMP	Isoleucine	Homofuraneol
	XMP	Isoleucine	Homofuraneol
	CMP	Isoleucine	Homofuraneol
	UMP	Isoleucine	Abhexon
	XMP	Isoleucine	Abhexon
	CMP	Isoleucine	Abhexon
	UMP	Isoleucine	Mesifuranone
	XMP	Isoleucine	Mesifuranone
	CMP	Isoleucine	Mesifuranone
	UMP	Isoleucine	Sotolon
	XMP	Isoleucine	Sotolon
	CMP	Isoleucine	Sotolon
	UMP	Lysine	Furaneol
	XMP	Lysine	Furaneol
	CMP	Lysine	Furaneol
	UMP	Lysine	Norfuraneol
	XMP	Lysine	Norfuraneol
	CMP	Lysine	Norfuraneol
	UMP	Lysine	Homofuraneol
	XMP	Lysine	Homofuraneol
	CMP	Lysine	Homofuraneol
	UMP	Lysine	Abhexon
	XMP	Lysine	Abhexon
	CMP	Lysine	Abhexon
	UMP	Lysine	Mesifuranone
	XMP	Lysine	Mesifuranone
	CMP	Lysine	Mesifuranone
	UMP	Lysine	Sotolon
	XMP	Lysine	Sotolon
	CMP	Lysine	Sotolon
	UMP	Threonine	Furaneol
	XMP	Threonine	Furaneol
	CMP	Threonine	Furaneol
	UMP	Threonine	Norfuraneol
	XMP	Threonine	Norfuraneol
	CMP	Threonine	Norfuraneol
	UMP	Threonine	Homofuraneol
	XMP	Threonine	Homofuraneol
	CMP	Threonine	Homofuraneol
	UMP	Threonine	Abhexon
	XMP	Threonine	Abhexon
	CMP	Threonine	Abhexon
	UMP	Threonine	Mesifuranone
	XMP	Threonine	Mesifuranone
	CMP	Threonine	Mesifuranone
	UMP	Threonine	Sotolon
	XMP	Threonine	Sotolon
	CMP	Threonine	Sotolon
	UMP	Valine	Furaneol
	XMP	Valine	Furaneol
	CMP	Valine	Furaneol
	UMP	Valine	Norfuraneol
	XMP	Valine	Norfuraneol
	CMP	Valine	Norfuraneol
	UMP	Valine	Homofuraneol
	XMP	Valine	Homofuraneol
	CMP	Valine	Homofuraneol
	UMP	Valine	Abhexon
	XMP	Valine	Abhexon
	CMP	Valine	Abhexon
	UMP	Valine	Mesifuranone
	XMP	Valine	Mesifuranone
	CMP	Valine	Mesifuranone
	UMP	Valine	Sotolon
	XMP	Valine	Sotolon
	CMP	Valine	Sotolon
	UMP	Ornithine	Furaneol
	XMP	Ornithine	Furaneol
	CMP	Ornithine	Furaneol
	UMP	Ornithine	Norfuraneol
	XMP	Ornithine	Norfuraneol
	CMP	Ornithine	Norfuraneol
	UMP	Ornithine	Homofuraneol
	XMP	Ornithine	Homofuraneol
	CMP	Ornithine	Homofuraneol
	UMP	Ornithine	Abhexon
	XMP	Ornithine	Abhexon
	CMP	Ornithine	Abhexon
	UMP	Ornithine	Mesifuranone
	XMP	Ornithine	Mesifuranone
	CMP	Ornithine	Mesifuranone
	UMP	Ornithine	Sotolon
	XMP	Ornithine	Sotolon
	CMP	Ornithine	Sotolon
	UMP	Hydroxyproline	Furaneol
	XMP	Hydroxyproline	Furaneol
	CMP	Hydroxyproline	Furaneol
	UMP	Hydroxyproline	Norfuraneol
	XMP	Hydroxyproline	Norfuraneol
	CMP	Hydroxyproline	Norfuraneol
	UMP	Hydroxyproline	Homofuraneol
	XMP	Hydroxyproline	Homofuraneol
	CMP	Hydroxyproline	Homofuraneol
	UMP	Hydroxyproline	Abhexon
	XMP	Hydroxyproline	Abhexon
	CMP	Hydroxyproline	Abhexon
	UMP	Hydroxyproline	Mesifuranone
	XMP	Hydroxyproline	Mesifuranone
	CMP	Hydroxyproline	Mesifuranone
	UMP	Hydroxyproline	Sotolon
	XMP	Hydroxyproline	Sotolon
	CMP	Hydroxyproline	Sotolon
	GMP from about 1% to	Hydroxyproline	Furaneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Hydroxyproline	Furaneol
	GMP	Hydroxyproline	Furaneol
	AMP	Hydroxyproline	Furaneol
	GMP from about 1% to	Hydroxyproline	Norfuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Hydroxyproline	Norfuraneol
	GMP	Hydroxyproline	Norfuraneol
	AMP	Hydroxyproline	Norfuraneol
	GMP from about 1% to	Hydroxyproline	Homofuraneol
	about 99% and IMP from
	about 1% to about 99%
	IMP	Hydroxyproline	Homofuraneol
	GMP	Hydroxyproline	Homofuraneol
	AMP	Hydroxyproline	Homofuraneol
	GMP from about 1% to	Hydroxyproline	Abhexon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Hydroxyproline	Abhexon
	GMP	Hydroxyproline	Abhexon
	AMP	Hydroxyproline	Abhexon
	GMP from about 1% to	Hydroxyproline	Mesifuranone
	about 99% and IMP from
	about 1% to about 99%
	IMP	Hydroxyproline	Mesifuranone
	GMP	Hydroxyproline	Mesifuranone
	AMP	Hydroxyproline	Mesifuranone
	GMP from about 1% to	Hydroxyproline	Sotolon
	about 99% and IMP from
	about 1% to about 99%
	IMP	Hydroxyproline	Sotolon
	GMP	Hydroxyproline	Sotolon
	AMP	Hydroxyproline	Sotolon

It should be noted that taurine is not included as an amino acid in respect of the invention. In fact, taurine is an organic sulfonic acid and lacks the carboxyl group which is characteristic of amino acids i.e. there is no COOH group. However in the art, such as described in US 2006/0286276 and US 2006/286275, taurine is often described as an amino acid, which is incorrect.

The invention also relates to, as a third aspect, a composition comprising one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones for use in increasing the acceptance and/or ensuring an adequate intake of a foodstuff in a companion animal. Increasing the palatability leads to increased enjoyment and acceptance of the foodstuff to the animal. Increased acceptance and enjoyment helps to overcome the fussiness of a companion animal with regard to food. Since the animal accepts and enjoys the foodstuff in accordance with the invention, it is more likely to reach its required daily calorie and nutrient intake.

The composition may be for use in increasing the appetising appeal of a foodstuff to an animal in order to encourage an animal to eat a healthy amount of foodstuff. Thus, the use of a composition comprising one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones in increasing the appetising appeal of a foodstuff; in encouraging a healthy intake of a foodstuff; in ensuring the required intake of nutrients and calories in a companion animal, is included in the present invention. By healthy level it is meant an amount that enables the animal to maintain or achieve an intake contributing to its overall general health in terms of micronutrients, macronutrients and calories. By this it is meant that an animal may eat sufficient calories and receive a nutritionally complete diet without needing to eat excess calories and thus maintaining a healthy balance, such as set out in the “Mars Petcare Essential Nutrient Standards”.

As mentioned above, the umami receptor has been studied as a target for flavour compounds. Many studies relating to the activation of the umami receptor focus on the human umami receptor. However, surprisingly the inventors have found that the umami receptor of humans differs in sequence to that of certain companion animals as shown in FIG. 18. Moreover, even though certain companion animals have shown preferences according to the art to particular amino acids, these preferences differ from animal to animal. Therefore, it is not possible to predict from work carried out in humans whether a companion animal would have the same response to the same amino acids.

In the human umami receptor, the key active site residues involved in glutamate and IMP binding have been identified by in silico modelling and by site-directed mutagenesis.

These studies show that the key residues are at positions H71, T149, S172, D192, Y220, E301 S306 and S385 and the residues are highly conserved in other species. A comparison of the human, pig, mouse and cat sequences showed only two changes in these particular residues (pig L220 and mouse A385).

The high level of conservation in these active site residues does not fit well with the different amino acid specificity for the umami receptor in the species studied. A study on pig umami receptors identified other residues in the active site that were reported as being important in binding. The amino acids in these locations were conserved between humans and pigs (R277, R307 and H308). On the basis of this similarity, pig umami was proposed as a model for human umami. However, the pig umami receptor showed a wide amino acid specificity (glutamate, alanine, asparagine, glutamine, serine and threonine) compared to the usual glutamate and aspartate ligands that are associated with human umami receptor activation. A report that used some other amino acids (glycine, alanine, serine) at high concentrations (up to 1M) suggested that these compounds delivered a umami sensation in humans but the effect was only monitored using sensory analysis and no receptor studies were reported. Thus it seems that the range of amino acids that activate the human umami receptor are very limited compared to other species and that the residues identified so far do not satisfactorily explain the difference in amino acid specificity between the pig and human umami receptors.

The invention also provides a method of enhancing the umami flavour/taste of a foodstuff, the method comprising adding to or including in the foodstuff one or more nucleotides, one or more amino acids consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones.

By enhancing it is meant that the umami flavour is detected more strongly/more intensely by the animal. It is thought that the addition of an amino acid complements the effect of the binding of a nucleotide to the umami receptor and vice versa. The addition of a furanone synergistically increases the umami flavour potency.

The present invention also provides a method of increasing an animal's preference for a foodstuff, the method comprising the addition of a nucleotide, an amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and a furanone to the foodstuff. Also provided is a method of enhancing the umami flavour of a foodstuff, the method comprising the addition of a nucleotide, an amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and a furanone to the foodstuff. A method of increasing the meaty (savoury) flavour of a foodstuff is also achieved by the use of a nucleotide, an amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and a furanone as described herein. The combination of the three components enables them to work in synergy to enhance umami flavour perception.

As a further aspect, the invention relates to a process for producing a pet foodstuff comprising one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones, the method comprising the steps of adding and mixing one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones with a pet foodstuff. The addition and/or mixing may be carried out prior to, during or after formulating, processing or packaging the foodstuff. The addition and/or mixing of the nucleotide, amino acid and furanone may be sequential or simultaneous.

All features of all aspects apply to all other aspects, mutatis mutandis.

The inventors have found that the addition of one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones to a pet food product significantly increases the preference of a companion animal for the foodstuff. The animals show a strong preference for a foodstuff or water comprising one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones over a foodstuff or water having none, or one or two of these compounds. This overcomes the difficulties associated with fussy animals and ensures an animal eats the entirety of the recommended daily amount of foodstuff provided to it, resulting in the health and wellbeing of the animal as well as the peace of mind of the owner.

The advantage, therefore, of a three component mixture for inclusion in a foodstuff is several-fold: an animal will be encouraged to eat the foodstuff on a consistent and long term basis; the synergistic effect means that a lower amount of each of the ingredients needs to be included in a foodstuff, meaning cost effective use of each of the nucleotide, amino acid and furanone.

Without wishing to be bound by theory, the present inventors believe that the umami taste receptor on the tongue of an animal can detect a nucleotide and that an amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine is detected by an alternative site on the umami receptor or by another receptor or receptors. Thus, the effect of combining both a nucleotide and such an amino acid in the composition provides more than an additive effect of each component individually to the animal, since more than one taste receptor mechanisms are activated and provide sensory feedback to the animal. This effect is further complemented by the addition of a furanone. The umami receptor is a heterodimeric transmembrane protein receptor and is also referred to in the art as T1R1/T1R3.

The present application shows that through in silico modelling of a non-human umami receptor and in vitro assays using a umami receptor the inventors have found that a subset of amino acids are able to bind to the umami receptor; however, the amino acids of the present invention, namely proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine exert their effect through a different mechanism. It has been shown that each of the amino acids of the present invention are palatable to an animal and thus, the amino acids of the invention bind to an alternative binding site or receptor or receptors in order to be perceived by the animal.

The nucleotides of the invention activate the umami receptor. As can be seen in FIG. 13, the receptor could be described in terms of a Venus Fly Trap, wherein the binding site consists of a structure similar to ‘jaws’, which close upon being bound by the nucleotide according to the invention. It is postulated that once the amino acid of the invention and the nucleotide has bound to their respective receptors, the furanone interacts synergistically to increase the umami flavour perception. This interaction may occur by cross talk between binding sites or receptors or during the transduction and neural processes.

The flytrap domain consists of two lobes, an upper lobe and a lower lobe that are connected by a region known as the hinge, (FIG. 13). The flytrap may transition from an open conformation to a closed conformation upon binding of a nucleotide.

The present inventors have shown that the amino acids according to the invention, namely proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine, ornithine and taurine do not activate the primary T1R1/T1R3 umami receptor site (as shown in FIG. 10). In vivo tests have indicated that animals respond positively to these amino acids as tastants. Therefore, by activating two separate receptors/pathways by the use of a nucleotide and an amino acid of the invention, the flavour experience for the animal is enhanced. Therefore, through careful research and investigation, combinations of tastants have been identified that are effective due to their ability to act separately but in a complementary manner to provide an increased perception of flavour to the animal. Previously, combinations of tastants have been used in the art without the consideration of whether they act on the same receptor or not. Clearly, two tastants that have an effect via the same binding site on a receptor will not contribute in an enhanced manner to the overall flavour of a foodstuff. By determining that the amino acids of the invention do not compete with the nucleotide or furanone of the invention, the inventors have established that palatability is increased, as shown by the in vivo experiments described herein.

Thus, the combination of a nucleotide and an amino acid of the invention appear to work together in a complementary manner and thus, increasing the perception of both compounds by the animal on the taste receptors when they are delivered together in a composition. Again, without wishing to be bound by theory, it appears that the amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and the nucleotide do not compete with each other in binding to the umami receptor since the amino acids appear to bind to an alternative receptor or receptors

Therefore, the use of the particular amino acids of the invention enhances the perception of flavour by the animal, which is further enhanced by the addition of a furanone.

It is noted that Yoshi et al., (Synergistic Effects of 5′-Nucleotides on Rat Taste Responses to Various Amino Acids, Brain Research, 367 (1986) 45-51), conclude that a synergistic effect is seen between the amino acids and nucleotides. However, the experiments described were not carried out in vivo, but rather utilised in vitro nerve signalling. Notably, it was assumed that a nerve response was concluded to be a positive response. However, as it is well known in the art, a nerve response can also be a negative response for an animal i.e. in vivo a nerve response could be a negative taste perception. Further, it can be seen that the amino acids discovered to be most responsive are not those that correlate to the information provided by the present invention. This is almost certainly due to the ‘artificial’ environment in which the amino acids were tested by Yoshi et al.,

US patent U.S. Pat. No. 3,524,747 describes the addition of a minimum of seven amino acids to a foodstuff to impart a “meaty” flavour. However, although a combination of seven amino acids could be contemplated by the present invention, the knowledge obtained by the inventors (that certain amino acids with a nucleotide and a furanone enhances the palatability of a foodstuff) enables fewer than seven amino acids to be utilised to increase the palatability of a foodstuff.

It is notable that none of the prior art known to the inventors contemplates the use of a nucleotide and amino acid, (particularly, an amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine) together with a furanone for enhancing the flavour of a foodstuff for a companion animal. As mentioned, these particular amino acids are not thought to bind to the umami receptor, rather they work in a synergistic way with a different mechanism of action, whereas other amino acids do appear to bind to the umami receptor.

The nucleotide, amino acid and furanone according to the present invention may be incorporated into any product which an animal, such as a dog or a cat, may consume in its diet. Thus, the invention covers standard food products, supplements, pet food, drinks, snacks and treats. The food product is preferably a cooked product. It may incorporate meat or animal derived material (such as beef, chicken, turkey, lamb, blood plasma, marrowbone etc. or two or more thereof). The food stuff alternatively may be meat free (preferably including a meat substitute such as soya, maize gluten or a soya product) in order to provide a protein source. The product may contain additional protein sources such as soya protein concentrate, milk proteins, gluten etc. The product may also contain a starch source, such as gelatinised starch, such as one or more grains (e.g. wheat, corn, rice, oats, barely etc) or may be starch free. A typical dry commercial cat and dog food contains about 10-70% crude protein, about 10-60% fat and the remainder being carbohydrate, including dietary fibre and ash. A typical wet, or moist product contains (on a dry matter basis) about 40% fat, 50% protein and the remainder being fibre and ash. The present invention is particularly relevant for a pet foodstuff as herein described which is sold as a diet, foodstuff or supplement for a cat or dog. In the present text the terms “domestic” dog and “domestic” cat mean dogs and cats, in particular Felis domesticus and Canis domesticus. Preferably, the pet foodstuff will meet the macronutrient requirements of an animal preferably a ratio of protein: fat: carbohydrate of approximately 50:40:10 for feline animals and 30:60:10 for a canine animal.

As can be seen from the examples, below, it has been surprisingly found that an amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine, a nucleotide and a furanone of the invention provide a greater than additive effect when presented to an animal. In other words, the preference of a companion animal for the combination of a nucleotide, an amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and a furanone is greater than an additive effect of the preference for any or each of the individual compounds. The addition of a furanone increases this preference to a greater extent. That is, inclusion of a furanone increases preference by more than the additive effect of the preference for the furanone alone.

Thus, the unexpected benefit of the combination of one or more nucleotides, one or more amino acids and one or more furanones is increased palatability. Without wishing to be bound by theory, the present inventors believe that this is due to the different receptors and/or binding sites for a nucleotide and for the amino acid; and the enhancing effect of furanone, as described above.

The invention will now be described in reference to the following Figures and Examples in which:

FIG. 1 shows the results in a difference test of a composition comprising 25 mM proline+2.5 mM IMP with a composition comprising 25 mM proline;

FIG. 2 shows the results in a difference test of a composition comprising 25 mM proline+2.5 mM IMP with a composition comprising 2.5 mM IMP;

FIG. 3 shows the results in a difference test of a composition comprising 25 mM threonine+2.5 mM GMP with a composition comprising 25 mM threonine;

FIG. 4 shows the results in a difference test of a composition comprising 25 mM threonine+2.5 mM GMP with a composition comprising 2.5 mM GMP;

FIG. 5 shows the results in a difference test of a composition comprising 25 mM valine+2.5 mM AMP with a composition comprising 25 mM valine; and

FIG. 6 shows the results in a difference test of a composition comprising 25 mM valine+2.5 mM AMP with a composition comprising 2.5 mM AMP;

FIG. 7 shows the results in a difference test of a composition comprising 25 mM proline+2.5 mM Ajitide+4 ppm fureneol with a composition comprising 25 mM proline+2.4mM Ajitide;

FIG. 8 shows the results in a difference test of a composition comprising 25 mM threonine+2.5 mM Ajitide+4 ppm fureneol with a composition comprising 25 mM threonine+2.5 mM Ajitide;

FIG. 9 shows the results in a difference test of a composition comprising 25 mM proline+2.5 mM GMP+fureneol with a composition comprising 25 mM proline+2.5 mM GMP;

FIG. 10 shows the resulting dose response curves of each amino acid of the invention that were screened in vitro for their ability to activate the T1R1/T1R3 receptor in the presence of 0.2 mM IMP.

FIG. 11 shows the dose response curves of nucleotides of the invention that were screened in vitro for their ability to activate the T1R1/T1R3 receptor in the presence of 20 mM alanine. The corresponding EC₅₀ values are shown in the table.

FIG. 12 shows the predicted structure of the T1R1/T1R3 umami receptor.

FIG. 13 shows a schematic of the predicted structure of the umami receptor; and

FIG. 14 shows a sequence alignment of the human, feline, canine, mouse and rat umami receptors.

EXAMPLES

All amino acids of the examples are in the L-form. Ajitide is a 50:50 mixture of GMP:IMP.

Example 1

Cats were allowed access to water containing either 25 mM proline+2.5 mM IMP with a composition comprising 25 mM proline The methodology used a 2-bottle choice test with 24 cats (the final number of cats for each test can vary due to data being discarded by spillage, etc.). Cats were housed individually during trial periods and had free access to water available between testing periods. The test involved a choice test between the tastant/mixture at a given concentration dissolved in deionised water versus deionised water only or another tastant/mixture. Control was made for positional bias (e.g. A/B exposure 1 and B/A exposure 2) and evaporation loss. The testing time was 36 hours (i.e. 18 hours per day, allowing a two-day crossover). Following two consecutive days of each testing, cats had two consecutive days of rest. Cats were offered a dry diet as a single meal at the start of the test period for one hour, calculated to meet the individual requirements for each cat.

The results are shown in the table below, and in FIG. 1.

Analysis of Intake g

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	23	40.20	0.0000	*
* a value of 0.000 indicates a valve of less than 0.0001.

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
	Product	Standard	95% Confidence
	Difference	Mean	Error	Lower	Upper
	Proline - Pro + IMP	−34.25	5.40	−45.42	−23.08

It can be seen that the amount of proline+IMP intake was on average 34.25 g more than proline alone intake, i.e. the combination of proline and IMP was significantly preferable to the animals over proline alone.

Example 2

The difference test was carried out as for Example 1, however, the composition containing 25 mM proline+2.5 mM IMP was compared with a composition containing 2.5 mM IMP only.

Results are shown in the table below and in FIG. 2.

Analysis of Intake g

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	23	45.83	0.0000

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
Product	Standard	95% Confidence Interval
Difference	Mean	Error	Lower	Upper
Pro + IMP - IMP	37.95	5.61	26.35	49.54

It can be seen that proline+IMP had a significantly higher intake, on average of 37.95 g, than IMP alone; i.e. the composition comprising both proline and IMP was preferable to the animals over IMP only.

The results of example 1 and 2 together show that a combination of histidine and IMP is significantly preferable than either of the compounds alone.

Example 3

A difference test was carried out as described in example 1 to compare a composition containing 25 mM threonine+2.5 mM GMP with a composition containing 25 mM threonine only.

The results are shown in the table below and in FIG. 3.

Analysis of Intake g

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	23	16.58	0.0005

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
Product	Standard	95% Confidence Interval
Difference	Mean	Error	Lower	Upper
Threonine - Thr + GMP	−43.77	10.75	−66.01	−21.53

It can be seen that the intake of threonine+GMP was, on average, 43.77 g more than the intake of threonine alone, and shows that the animals significantly prefer the combination of threonine and GMP to threonine alone.

Example 4

The difference test was carried out as described in example 3; however the composition containing 25 mM threonine+2.5 mM GMP was compared with a composition containing 2.5 mM GMP only.

The results are shown in the table below and in FIG. 4.

Analysis of Intake g

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	23	38.69	0.0000

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
Product	Standard	95% Confidence Interval
Difference	Mean	Error	Lower	Upper
Thr + GMP - GMP	24.34	3.91	16.24	32.43

It can be seen that the intake of threonine+GMP was, on average, 24.34 g more than the intake of GMP alone, and shows that the animals significantly prefer the combination of threonine+GMP to GMP alone.

The results of example 3 and 4 together show that a combination of threonine and GMP is significantly preferable to either of the compounds alone.

Example 5

A difference test was carried out as described in example 1 to compare a composition containing 25 mM valine+2.5 mM AMP with a composition containing 25 mM valine alone.

The results are shown in the table below and in FIG. 5.

Analysis of Intake g

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	22	26.94	0.0000

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
Product	Standard	95% Confidence Interval
Difference	Mean	Error	Lower	Upper
Valine - Val + AMP	−25.82	4.97	−36.14	−15.50

It can be seen that the intake of valine+AMP was, on average, 25.82 g more than the intake of valine alone, and shows that the animals significantly prefer the combination of valine+AMP to valine alone.

Example 6

The difference test was carried out as described in example 5 to compare a composition containing 25 mM valine+2.5 mM AMP with a composition containing 2.5 mM AMP.

The results are shown in the table below, and in FIG. 6.

Analysis of Intake g

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	23	13.70	0.0012

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
Product	Standard	95% Confidence Interval
Difference	Mean	Error	Lower	Upper
Val + AMP - AMP	13.96	3.77	6.16	21.77

It can be seen that the intake of valine+AMP was, on average, 25.92 g more than the intake of AMP alone, and shows that the animals significantly prefer the combination of valine+AMP to AMP alone.

The results of example 5 and 6 together show that a combination of valine and AMP is significantly preferable to either of the compounds alone.

Example 7

The difference test was carried out as described in example 1 to compare a composition containing 25 mM proline+2.5 mM Ajitide+4 ppm fureneol with a composition containing 25 mM proline+2.5 mM Ajitide.

The results are shown in the table below, and in FIG. 7.

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	24	11.74	0.0022

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
Product	Standard	95% Confidence Interval
Difference	Mean	Error	Lower	Upper
Pro + Aji + Fur -	18.00	5.25	7.15	28.84
Pro + Aji

It can be seen that the intake of proline+Ajitide+fureneol was, on average, 18.00 g more than the intake of proline+Ajitide, and shows that the animals significantly prefer the combination of proline+Ajitide+fureneol to proline and Ajitide alone.

Example 8

The difference test was carried out as described in example 1 to compare a composition containing 25 mM threonine+2.5 mM Ajitide+4 ppm fureneol with a composition containing 25 mM threonine+2.5 mM Ajitide.

The results are shown in the table below, and in FIG. 8.

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	23	37.91	0.0000

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
Product	Standard	95% Confidence Interval
Difference	Mean	Error	Lower	Upper
Thr + Aji + Fur -	38.39	6.23	25.49	51.28
Thr + Aji

It can be seen that the intake of threonine+Ajitide+fureneol was, on average, 38.39 g more than the intake of threonine+Ajitide, and shows that the animals significantly prefer the combination of threonine+Ajitide+fureneol to threonine+Ajitide alone.

Example 9

The difference test was carried out as described in example 1 to compare a composition containing 25 mM proline+2.5 mM GMP+4 ppm fureneol with a composition containing 25 mM proline+2.5 mM GMP.

The results are shown in the table below, and in FIG. 9.

ANOVA Table for Fixed Effects
	Degrees of Freedom
Factor	Numerator	Denominator	F-value	P-value
Product Difference	1	24	83.57	0.0000

Table of Mean Product Difference, Standard
Error & 95% Confidence Intervals
Product	95% Confidence Interval
Difference	Mean	Standard Error	Lower	Upper
Pro + GMP + Fur -	40.99	4.48	31.74	50.25
Pro + GMP

It can be seen that the intake of proline+GMP+fureneol was, on average, 40.99 g more than the intake of proline+GMP, and shows that the animals significantly prefer the combination of proline+GMP+fureneol to proline+GMP alone.

The results of example 7, 8 and 9 together show that the addition of fureneol significantly increases the palatability.

Example 10

In vitro screening was carried out in order to establish which amino acids bind or do not bind to the known umami binding site. The results of the testing of the amino acids of the present invention are shown in FIG. 10. It can be seen that none of the amino acids of the present invention activate the umami receptor.

Claims

1. Use of one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones for increasing the palatability of a foodstuff to a companion animal.

2. The use according to claim 1, wherein the one or more nucleotides are selected from the group consisting of CMP, XMP, UMP, AMP, GMP and IMP.

3. The use according to claim 2, wherein the one or more nucleotides is a mixture of GMP and IMP.

4. The use according to claim 1, wherein the one or more furanones are a compound according to formula I or formula II

5. The use according to claim 1, wherein the one or more furanones is are selected from the group consisting of furaneol, homofuraneol, sotolon, norfuraneol, abhexon, mesifuranone or dimethoxyfuranone, as defined in Table 1.

6. The use according to claim 1, wherein the nucleotide, the amino acid and the furanone are in addition to any nucleotides, amino acids and furanones that may be found in any meat, vegetable or dairy component of the foodstuff.

7. The use according to claim 1, wherein the one or more nucleotides are present in an amount of less than 100 mM.

8. The use according to claim 1, wherein the one or more amino acids are present at an amount of less than 1M.

9. The use according to claim 1, wherein the one or more furanones are present at an amount of less than 40 ppm.

10. One or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones for use in increasing the acceptance of a pet foodstuff in a companion animal.

11. A nucleotide, an amino acid and a furanone for use according to claim 10, wherein the acceptance is a preference for a foodstuff comprising the nucleotide, amino acid and furanone over a foodstuff that does not comprise a nucleotide, an amino acid and a furanone.

12. A pet foodstuff comprising one or more nucleotides, one or more amino acids selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine, and one or more furanones.

13. A pet foodstuff according to claim 12, wherein the one or more nucleotides, the one or more amino acids and the one or more furanones are in a combination selected from the group consisting of: GMP between 1 to 99% and IMP between 1 to 99%, Threonine and Furaneol;GMP between 1 to 99% and IMP between 1 to 99%, Valine and Furaneol;GMP between 1 to 99% and IMP between 1 to 99%, Proline and Sotolon;GMP between 1 to 99% and IMP between 1 to 99%, Threonine and Sotolon;GMP between 1 to 99% and IMP between 1 to 99%, Valine and Sotolon;IMP, Proline and Furaneol;IMP, Threonine and Furaneol;IMP, Valine and Furaneol;IMP, Proline and Sotolon;IMP, Threonine and Sotolon;IMP, Valine and Sotolon;GMP, Proline and Furaneol;GMP, Threonine and Furaneol;GMP, Valine and Furaneol;GMP, Proline and Sotolon;GMP, Threonine and Sotolon; andGMP, Valine and Sotolon.

14. A method for increasing acceptance of a foodstuff in a companion animal comprising allowing the animal access to a foodstuff comprising at least one nucleotide, at least one amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine and one or more furanones.

15. A process of preparing a pet foodstuff comprising at least one nucleotide, at least one amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine, and one or more furanones, the process comprising the steps of adding and mixing at least one nucleotide, at least one amino acid and one or more furanones with a pet foodstuff.

16. A process of preparing a pet foodstuff according to claim 15, wherein the process comprises combining one or more pet food ingredient; the at least one amino acid; the at least one nucleotide; and the one or more furanones, wherein the amino acid, nucleotide and furanones are added together or separately, and wherein the amino acid, the nucleotide and the furanones together provide no more than 30 wt % of the dry matter that is contained in the foodstuff.

17. A process according to claim 16, wherein the one or more pet food ingredients include one or more of the edible materials selected from meat, animal fat, blood plasma, marrowbone, vegetable protein, vegetable fat, milk protein, grains and starch, wherein the one or more edible ingredients provide at least 60 wt % of the dry matter that is contained in the pet foodstuff.

18. A method for increasing the palatability of a foodstuff, the method comprising adding to a foodstuff during or after manufacture at least one nucleotide, at least one amino acid selected from the group consisting of proline, hydroxyproline, glutamic acid, aspartic acid, arginine, cystine, glutamine, isoleucine, lysine, threonine, valine and ornithine, and one or more furanones.

19. A pet foodstuff produced by the method of claims 15.