Hostname: page-component-cd9895bd7-8ctnn Total loading time: 0 Render date: 2024-12-23T05:58:20.144Z Has data issue: false hasContentIssue false

Development of a novel bioassay for determining the available lysine contents of foods and feedstuffs

Published online by Cambridge University Press:  01 June 2007

Shane M. Rutherfurd*
Affiliation:
Institute of Food Nutrition and Human Health, Massey University, Palmerston North, New Zealand
Paul J. Moughan
Affiliation:
Riddet Centre, Massey University, Palmerston North, New Zealand
*
*Corresponding author: Shane M. Rutherfurd, fax +64 6 350 5657, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Lysine is an important indispensable amino acid, and describing the lysine content of a food or feedstuff provides useful information about nutritional value. However, when a food or feedstuff is subjected to heating the lysine present can be altered to nutritionally unavailable derivatives. These derivatives can revert back to lysine during the acid hydrolysis step used in amino acid analysis causing an overestimate of the lysine content. There have been many chemical methods developed to determine the reactive (unmodified) lysine content of foods and feedstuffs, but these do not take into account the incomplete absorption of lysine from the small intestine. There are also a number of animal-based assays for determining available lysine (the lysine that can be absorbed in a form that can be used for protein synthesis). The true ileal amino acid digestibility assay is commonly used to determine amino acid availability and is accurate for application to unprocessed foods and feedstuffs but is not accurate for lysine and possibly other amino acids when applied to heat-processed foods or feedstuffs. For such protein sources, assays such as the slope-ratio assay, indicator amino acid oxidation assay and the BIOLYSINE™ assay (true ileal digestible reactive lysine assay) have been developed to determine available lysine. The present paper discusses the efficacy of the BIOLYSINE™ assay as well as other assays for determining available lysine in processed foods and feedstuffs.

Type
Research Article
Copyright
Copyright © The Author 2007

Introduction

Lysine (2,6-diaminohexanoic acid) is one of the twenty-two amino acids found in plant and animal proteins. Lysine is found in relatively low amounts in many cereals, such as wheat and rice, but tends to be more abundant in legumes, milk and meat-based foods. From a nutritional standpoint, lysine is an indispensable dietary essential amino acid that can only be derived from the diet and is often the first limiting amino acid for production animals (pigs and poultry). Lysine can also be limiting in diets for man, especially diets that are high in cereals and low in animal proteins.

During the processing of foods and feedstuffs, lysine can be chemically modified to form acid-labile derivatives. As a result of the presence of these derivatives, conventional methods of assessing lysine availability which use traditional amino acid analysis (for example, ileal amino acid digestibility assays) are inaccurate. Considerable effort has gone into developing alternative methods that accurately determine lysine and digestible lysine content. In the present review, we outline and discuss a bioassay which has been developed in our laboratory that overcomes the analytical problems associated with lysine to accurately predict the available lysine content of processed foods and feedstuffs.

Lysine and processing

Lysine is a basic amino acid and possesses a reactive amino group on its side chain. This ɛ-amino group can undergo reactions with a wide variety of compounds including reducing sugars, fats and their oxidation products, polyphenols, vitamins, food additives and other amino acidsReference Hurrell and Carpenter1. Perhaps the most important lysine modification is that which occurs with reducing sugars (Maillard reaction). Several excellent reviews have been published describing this reactionReference Friedman2, Reference Finot, Bujard, Mottu, Mauron and Friedman3 and it is not the intention to repeat that discussion here. However, a brief synopsis of the reaction is presented. The reducing sugar–lysine Maillard reaction initially involves a reversible condensation reaction which results in the formation of a Schiff's base. The Schiff's base then undergoes irreversible rearrangement to produce ɛ-N-deoxyketosyllysine (Amadori product), also known as the early Maillard productReference Finot, Bujard, Mottu, Mauron and Friedman3. The Amadori product can then further react to produce brown pigments or melanoidins (late Maillard products) but these reactions are not well definedReference Hurrell and Carpenter1. Other amino acids are also believed to undergo Maillard-type reactions, for example, prolineReference Mills and Hodge4, Reference Tressl, Wondrak, Kersten and Rewicki5, tryptophanReference Saito, Okitani, Hayase and Kato6, Reference Friedman and Cuq7 and arginineReference Konishi, Hayase and Kato8 but these reactions are less well studied.

The nutritional availability of the Maillard reaction intermediates has been studied. Using a rat assay where the growth of rats fed graded levels of lysine was compared with those fed Schiff's bases similar to those formed during the Maillard reaction, Finot et al. Reference Finot, Bujard, Mottu, Mauron and Friedman3 reported near-complete utilisation for the Schiff's base. It has been postulated that utilisation is via reversion to the aldosylamine derivative of lysine which can then be easily hydrolysed to lysineReference Finot, Bujard, Mottu, Mauron and Friedman3. In contrast, biological availability of ɛ-N-deoxyketosyllysine (Amadori product, early Maillard product) has been found to be low (5–15 %) by some workersReference Finot, Finot, Aeschbacher, Hurrell and Liardon9 and nil by othersReference Finot, Bujard, Mottu, Mauron and Friedman3, Reference Hurrell, Carpenter and Friedman10.

Maillard damage of lysine is generally slow, sometimes taking many months before significant amounts of lysine in a food or feedstuff are modified even at ambient temperaturesReference Rutherfurd and Moughan11. However, there are a number of factors that control the rate of Maillard product formation, including temperature, pH, water activity and reactant concentrationReference Franzen, Singh and Okos12. Many foods or feedstuffs undergo processing during their manufacture to either improve palatability, functionality or food safetyReference Hendriks, Emmens, Trass and Pluske13, during which, foods and feedstuffs are subjected to heat, pH extremes and pressure, all of which can greatly accelerate Maillard product formation.

In the intensive livestock industry accurate diet formulation is critical for maximising financial return and since lysine is the first limiting amino acid for growth in most pig and poultry diets, protecting lysine from damage during processing is important. Accurate data on the lysine content of diets and protein sources is also critical for efficient diet formulation. In human nutrition, many of the protein sources consumed by infants, children and adults are processed (for example, milk products, breakfast cereals and breads) and food is often cooked for safety or to enhance flavour and aroma. These practices accelerate the formation of advanced Maillard products. Indeed it is some of these advanced Maillard products that are responsible for flavour and aroma enhancement. Many Western diets tend to be high in meat and milk products. Since these foodstuffs contain high amounts of lysine, lysine damage may not be a critical problem nutritionally, in practice. However, for diets high in cereals and low in meat and milk, lysine can be limiting and this can have health implications, particularly for growing children.

The fate of lysine during chemical analysis

The lysine content of foods is usually determined using amino acid analysis. Proteins consist of a chain of amino acids held together with peptide bonds. During analysis the peptide bonds are hydrolysed by heating the protein in concentrated acid (6 m-HCl) at 110°C for 24 hReference Hirs, Stein and Moore14. The resulting free amino acids are then quantified using HPLC. This hydrolysis procedure was developed by Moore & Stein in the 1950s and has changed little over the decades. However, when heat-processed protein sources which may contain early Maillard products undergo acid hydrolysis these products are further modified to a number of other compounds. For example, hydrolysis of processed malt products can lead to the formation of carboxymethyllysineReference Hartkopf, Pahlke, Lüdeman and Erbersdobler15. Acid hydrolysis of heated milk converts fructosyl lysine to a mixture of lysineReference Mauron, Mottu, Bujard and Eggli16, furosineReference Heyns, Heukeshoven and Brose17, Reference Finot, Bricout, Viani and Mauron18 and pyridosineReference Finot, Viani, Bricout and Mauron19. Since some of the early Maillard products revert back to lysine during acid hydrolysis, the traditional amino acid analysis procedure is not suitable for quantifying lysine in processed protein sources (Fig. 1). Inaccurate and misleading terminology has evolved, for example, the term ‘total lysine’ is deemed to be the lysine determined by traditional amino acid analysis of a food in which early Maillard compounds are present. Total lysine constitutes the unmodified lysine present in the food plus the lysine that has reverted back from the early Maillard products during acid hydrolysis. The term total lysine is therefore as inaccurate as calling two different compounds one compound, simply because they co-elute on the HPLC. Lysine that has reverted back from early Maillard compounds during acid hydrolysis should not be referred to as lysine in any way and does not represent the lysine in the food in any way. It is simply an artifact of the amino acid analysis procedure. The early Maillard products only revert to lysine under conditions of acid hydrolysis and do not revert to lysine during the milder hydrolysis conditions encountered in the mammalian or avian digestive tract thus rendering them nutritionally unavailable.

Fig. 1 The fate of lysine during processing and analysis. (A) Unprocessed protein source; (B) processed protein source.

Lysine terminology

Total lysine, reactive lysine, chemically available lysine, available lysine and biologically available lysine are all terms used to describe the lysine content of foods and there appears to be considerable confusion as to the appropriate terminology to use. Many workers have determined chemically reactive lysine using chemical tests and described it as available lysineReference Milán-Carillo, Gutiérrez-Dorado, Perales-Sánchez, Cuevas-Rodríguez, Ramírez-Wong and Reyes-Moreno20Reference Couch and Thomas27, reactive lysineReference Rutherfurd and Moughan11, Reference Rutherfurd, Markwick-Rutherfurd and Moughan28Reference Rao, Carter and Frampton40, chemically available lysineReference Desrosiers, Savoie, Bergeron and Parent41, Reference Moughan, Schrama, Skilton and Smith42, chemically reactive lysineReference Henle, Walter and Klostermeyer43 and total available lysineReference Rehman44. Furthermore, some workers have determined lysine using conventional amino acid analysis and refer to this as available lysineReference Undi, Moshtaghi, Wittenberg and Ingalls45 and furosine levels have also been determined and related to undamaged lysine which has then been termed bioavailable lysineReference Moughan, Gall and Rutherfurd46, Reference Erbersdobler and Hupe47. Moreover, the terms available lysine and bioavailable lysineReference Rutherfurd and Moughan11, Reference Rutherfurd, Markwick-Rutherfurd and Moughan28Reference Rutherfurd and Moughan30, Reference Rutherfurd and Moughan32, Reference Rutherfurd, Moughan and van Osch33 have been used to describe the unmodified lysine units that are absorbed in a form that can be potentially utilised for protein synthesis, catabolism or conversion. The terms available lysineReference Batterham, Andersen, Baigent, Darnell and Taverner48Reference Batterham, Lowe, Darnell and Major50 and bioavailable lysineReference Lumpkins and Batal51Reference Noll, Waibel and Behrends57 have also been used to describe the unmodified lysine units that are utilised for protein synthesis only.

Clearly, there is considerable discrepancy and perhaps misunderstanding surrounding the appropriate terminology for describing ‘available lysine’ depending on the method used to determine it. In our laboratory and following Hurrell & CarpenterReference Hurrell and Carpenter38, we refer to the undamaged lysine residues (lysine that has not undergone Maillard reactions or similar and possesses a side-chain amino group that is free to react) determined using any chemical method that targets the unreacted ɛ-amino group of lysine (for example, fluorodinitrobenzene (FDNB), trinitrobenzenesulfonic acid, sodium borohydride, guanidination, dye-binding method, or any chemical method that can be related back to undamaged lysine, such as the furosine method), as reactive lysine or chemically reactive lysine. Furthermore, we refer to the undamaged lysine residues that are digested and absorbed (i.e. absorbed reactive lysine) by an animal or human subject consuming the feed or food as available or bioavailable lysine (i.e. potentially available for body protein synthesis). We use the term total lysine to indicate the reactive lysine plus the lysine that has reverted back from Maillard products during acid hydrolysis (reactive + reverted lysine). The latter terminology will be used for the remainder of the present review. We would view any undamaged lysine residues that are digested, absorbed and potentially available for utilisation (either protein synthesis, catabolism or conversion) by an animal or human subject as utilisable lysine. Finot & HurrellReference Finot, Hurrell, Finley and Hopkins58 concur that availability and utilisability are two separate parameters and should not be confused. BatterhamReference Batterham59 is also in agreement in that an appropriate definition for amino acid availability would be ‘the proportion of the total amino acid that is digested and absorbed in a form suitable for protein synthesis’.

Determining reactive lysine

There have been many methods developed to determine reactive lysine, including chemical and biological assays. For the chemical assays, most are based on specific reactions with the ɛ-amino group of lysine. The most well-known method is the FDNB methodReference Carpenter60 which uses the Sanger reaction to convert lysine to dinitrophenyl-lysine which is extracted and measured spectrophotometrically or by HPLC. This method has been applied to animal feedstuffsReference Hendriks, Moughan, Boer and van der Poel34, Reference Noll, Waibel and Behrends57, breakfast cerealsReference Fernandez-Artigas, Garcia-Villanova and Guerra-Hernandez24, Reference Horvatić and Guterman25, Reference Torbatinejad, Rutherfurd and Moughan31, Reference Carpenter, Steinke, Catigani, Swaisgood, Allred, MacDonald and Schelstraete61, meatReference Carpenter, Steinke, Catigani, Swaisgood, Allred, MacDonald and Schelstraete61, Reference Rayner and Fox62 and milkReference Carpenter, Steinke, Catigani, Swaisgood, Allred, MacDonald and Schelstraete61. However, the method underestimates the reactive lysine content of foods since some of the dinitrophenyl-lysine may be destroyed during the acid-hydrolysis step used to liberate the dinitrophenyl-lysine from the proteinReference Booth63, necessitating the use of correction factors. Rao et al. Reference Rao, Carter and Frampton40 developed the FDNB-difference method where the lysine content was determined both before and after reaction with FDNB and the difference represented the reactive lysineReference Rutherfurd and Moughan32, Reference Rao, Carter and Frampton40, Reference Van Barneveld, Batterham and Norton64. Another shortcoming with this assay is that FDNB will react with α-amino groups as well as the ɛ-amino group of lysine, so significant levels of free amino acids or peptides in the food will cause an overestimation of reactive lysine contentReference Carpenter, Bjarnason, Bender, Kihlberg, Löfqvist and Munck65. Recently, HPLC has been used to separate and quantify the dinitrophenyl-lysine, but this still does not overcome the problem of doubly labelled free lysine, a particular problem whereby synthetic lysine has been added to the diet or food. Other methods for determining reactive lysine include the trinitrobenzenesulfonic acid methodReference Kakade and Leiner66, sodium borohydride methodReference Hurrell and Carpenter38, furosine methodReference Desrosiers, Savoie, Bergeron and Parent41, dye-binding methodReference Hendriks, Moughan, Boer and van der Poel34, ninhydrin-reactive lysine methodReference Friedman, Pang and Smith36, o-phthaldialdehyde-reactive lysine methodReference Vigo, Malec, Gomez and Llosa35 and guanidination methodReference Mao, Lee and Erbersbobler26, Reference Torbatinejad, Rutherfurd and Moughan31, Reference Rutherfurd, Moughan and van Osch33, Reference Mauron and Bujard67, Reference Maga68.

The guanidination method involves the reaction of the ɛ-amino group of lysine with o-methylisourea to produce homoarginine. Homoarginine is acid stable, so after guanidination proteins can undergo amino acid analysis in the traditional manner and the determined homoarginine represents the reactive lysine present. This reaction has been used to modify protein for functional studiesReference Hettinger and Harbury69Reference Hughes, Saroff and Carney73, to produce low-lysine or lysine-free diets for determining endogenous ileal lysine loss in pigs and poultryReference Rutherfurd, Chung and Moughan74Reference Hagemeister and Erbersdobler80 as well as for determining the reactive lysine content of foods and feedstuffsReference Mao, Lee and Erbersbobler26, Reference Rutherfurd and Moughan30Reference Rutherfurd, Moughan and van Osch33, Reference Moughan and Rutherfurd81.

An important prerequisite for the successful application of the guanidination reaction for determining the reactive lysine content of foods or feedstuffs is that the conversion of lysine to homoarginine is complete. Consequently, considerable work has been conducted to this endReference Maga68, Reference Rutherfurd and Moughan82, Reference Möller, Andrews and Cheeseman83. In our laboratory we routinely use unheated purified proteins (for example, lysozyme) as standards which are guanidinated along with test samples to ensure that the guanidination reagent is adequately prepared and that the incubation conditions are optimal.

The guanidination method works equally well with both unprocessed and processed proteins. In an unprocessed food or feed, there are no early Maillard products and, consequently, total lysine is equivalent to reactive lysine (Fig. 1). However, in a processed product where early Maillard products, or any other acid-labile lysine derivative which reverts to lysine in the presence of hot acid, are present, then total lysine overestimates reactive lysine by including reverted lysine in its estimation. When guanidination is used, the reaction takes place before acid hydrolysis so all the reactive lysine is converted to acid-stable homoarginine before being exposed to acid. During acid hydrolysis, some of the early Maillard products revert to lysine but this reverted lysine does not get included in the reactive lysine measurement since reactive lysine is represented by the homoarginine content only. The presence of a lysine peak in the chromatogram of a guanidinated processed feed or food has created certain confusion around the use of the guanidination reaction to determine reactive lysine. It has been thought that the presence of a lysine peak suggests that the guanidination reaction has not been complete. This is not the case.

Rigorous quality control using unprocessed protein standards and the development of appropriate reaction conditions for the reaction are required. If this is ensured, then the analyst can be confident that all lysine observed after hydrolysis of a guanidinated feed or food is not unguanidinated reactive lysine but rather reverted lysine. In carefully controlled studies, we have shown an excellent correlation between the reactive lysine content determined using the guanidination reaction with that determined using the FDNB method for a range of animal feedstuffs and breakfast cereals (Fig. 2)Reference Torbatinejad, Rutherfurd and Moughan31, Reference Rutherfurd, Moughan and van Osch33.

Fig. 2 Comparison of the reactive lysine content of (A) selected breakfast cereals (r 0·985 (P < 0·001); y = 1·05x+0·01) and (B) selected animal feedstuffs (blood meal, meat and bone meal, wheat meal, soyabean meal and cottonseed meal (r 0·996 (P < 0·001); y = 1·04x+1·21) determined using either the guanidination reaction or the fluorodinitrobenzene (FDNB) method. (—), Complete agreement between the two methods. (Reproduced with permission from Torbatinejad et al. Reference Torbatinejad, Rutherfurd and Moughan31 and Rutherfurd et al. Reference Rutherfurd, Moughan and van Osch33; copyright 2005, 1997 American Chemical Society.)

There has also been confusion around the presence of reverted lysine in that some workers who have used the guanidination reaction to determine the reactive lysine content of feedstuffs or foods believe that the sum of the reactive lysine and the reverted lysine determined after guanidination should equal the total lysine determined without guanidination. While this may occur sometimes, it is our experience that this is generally not the case and should not necessarily be expected to be so. Guanidination of a feedstuff or food is conducted in the presence of concentrated o-methylisourea at a high pH and may take place over several days. During this time it is possible (indeed likely) that early Maillard products are converted to other acid-stable products, such as late Maillard products. The resulting lower concentration of early Maillard products will result in a lower amount of reverted lysine than is observed in the unguanidinated corresponding food or feedstuff. Furthermore, during acid hydrolysis it is possible that the kinetics of the reversion reaction from early Maillard product to lysine are altered in the presence of high concentrations of o-methylisourea and barium sulfate, leading to different proportions of early Maillard product reverting to lysine than would occur in the feedstuff or food alone during conventional amino acid analysis without prior guanidination.

Another advantage of the guanidination method over all the other reactive lysine assays is that o-methylisourea will only react with the ɛ-amino group of lysine and does not react with the α-amino group of lysine or any other amino acidReference Kassell and Chow70Reference Klee and Richards72, Reference Moughan and Rutherfurd81, Reference Zhang, Li, Qiao, Wang, Chen and Thacker84Reference Chervenka and Wilcox87 with the exception of glycineReference Wang, Xu, McGrath, Patterson, Neckers and Cotter88. Consequently, the guanidination reaction can be used to determine free lysine or peptide-bound lysine, and permits the accurate determination of reactive lysine content of diets that have been supplemented with synthetic lysine. The same cannot be said for the FDNB assay or any other reactive lysine assays.

Determining available lysine

There are a number of assays that determine protein-bound reactive lysine in foods and feedstuffs with reasonable accuracy, some of which have been described earlier. However, the failing of these assays is that they do not take into account the possibility that the digestion and absorption of unmodified lysine in a food protein may be less than 100 %. This is an important consideration since the amino acid (including reactive lysine) digestibility of processed foods or feedstuffs is often far from completeReference Rutherfurd, Torbatinejad and Moughan29, Reference Rutherfurd and Moughan32, Reference Batterham, Andersen, Baigent, Darnell and Taverner48, Reference Van Barneveld, Batterham and Norton64, Reference Wiseman, Jagger, Cole and Haresign89. Moughan et al. Reference Moughan, Gall and Rutherfurd46 using a heated glucose–casein mixture clearly demonstrated that considerable amounts of dietary reactive lysine were not absorbed from the small intestine of the growing pig (Table 1).

Table 1 The amount of total lysine, fluorodinitrobenzene (FDNB)-reactive lysine, reactive lysine and absorbed reactive (available) lysine in a heated glucose–casein mixture (reproduced with permission from Moughan et al. Reference Moughan, Gall and Rutherfurd46; copyright 1996 American Chemical Society)

* Determined using conventional amino acid analysis.

† Determined using the furosine method.

‡ Determined from the furosine levels in the diet and digesta of pigs fed a heated glucose–casein diet.

The most accurate means of determining amino acid digestibility is the true ileal amino acid digestibility assay. This methodology is discussed in detail by MoughanReference Moughan90. A test diet containing the feedstuff or food that is being tested is fed to an animal or human subject and digesta are collected from the terminal ileum just anterior to the ileo-caecum junction (ileal digesta). The amino acid content of the diet and digesta are determined using amino acid analysis and related to dietary intake by use of an indigestible marker. Ileal amino acid digestibility is calculated from the difference in amino acid content of the diet and digesta. There are a number of methods used to collect ileal digesta including nasogastric tube intubation, the cooperation of ileostomates, cannulating the terminal ileum of animals (ileal cannulation), removing the large intestine (ileo-rectal anastomosis) and collection under anaesthesia and direct sampling. Several reviews discussing these and other methods of ileal digesta collection have been publishedReference Hodgkinson, Moughan, Moughan, Verstegen and Visser-Reyneveld91Reference Batterham and D'Mello93.

For protein sources that have not been damaged during processing or storage, the ileal amino acid digestibility assay seems to accurately determine the amount of amino acid that is delivered to the animal's body in a form that can be utilised (available amino acid content). However, since amino acid analysis is used to determine the amino acid content of both the diet and digesta, then for processed protein sources, ileal digestibility may not be accurate for all amino acids, especially lysine, threonine, methionine and tryptophanReference Batterham59. The analytical problems associated with determining lysine in processed feedstuffs resurface when trying to measure the lysine content of ileal digesta leading to erroneous digestibility coefficients.

Slope-ratio assay

One alternative to using ileal digestibility to determine lysine availability in processed protein sources is the use of animal growth assays. These assays include the protein efficiency ratio, net protein utilisation, biological valueReference Bodwell94 and, arguably the most important, the slope-ratio assay. These methods are all based on the ability of an animal to deposit amino acids or protein from a test diet into the animal's body. Protein deposition in the animals fed the test protein source is compared with that in animals fed a series of standard diets with known and often graded levels of a limiting amino acid supplied in its synthetic form. While these assays overcome the analytical difficulties in determining lysine in processed protein sources and the resulting inaccuracy of the ileal digestibility assay when applied to lysine in processed foods or feedstuffs, they may also be flawed in that the efficiency with which protein-bound lysine, which would be present in the test protein, is utilised may be different from that of the synthetic form. Batterham et al. Reference Batterham, Murison and Lewis95 developed and used the slope-ratio assay to determine the biologically available lysine content of processed meals for pigs. The assay was based on feeding test animals diets containing graded levels of synthetic lysine and a curve relating body growth to lysine addition was plotted. The same was repeated for a test protein with graded amounts of protein added to a series of test diets. By comparing the slopes for the synthetic lysine diets (standard diet) (where all the lysine is assumed to be utilised) with those for the test-protein diets, the available lysine content of the test protein can be estimated.

The slope-ratio assay has been applied to cottonseed meal, meat meals and sunflowerseed meal, rapeseed meal, skimmed milk powder and soyabean mealReference Fernandez and Parsons55, Reference Batterham, Murison and Lewis95, meat and bone mealReference Batterham, Lowe, Darnell and Major50, Reference Wang and Parsons53, blood mealReference Batterham, Lowe, Darnell and Major50, distillers dried grainsReference Lumpkins and Batal51, maizeReference Parsons, Zhang and Araba54 and heated field peasReference Van Barneveld, Batterham and Norton49. Similar methods have been developedReference McDonough, Hitchins, Bodwell and Staples56, Reference Faldet, Satter and Broderick96 that use rat growth assays to determine the available lysine content in heated protein sources. These methods are similar to the slope-ratio assay but instead of using standard diets containing graded levels of synthetic lysine to plot against animal growth, Faldet et al. Reference Faldet, Satter and Broderick96 used wheat gluten-based standard diets with graded levels of available lysine supplied from the wheat gluten where the reactive lysine had previously been determined using the FDNB-difference method. AdeolaReference Adeola97 used the slope-ratio assay to determine the available tryptophan in soyabean meal using 10 kg pigs. For severely processed protein sources, the slope-ratio assay gives superior information to the traditional ileal digestibility assay and considerable work has been conducted to compare these two assays. Batterham et al. Reference Batterham, Andersen, Baigent, Darnell and Taverner48 showed that ileal digestible lysine determined using traditional amino acid analysis overestimated the available lysine content of cottonseed meal but not high-quality soyabean meal when fed to growing pigs. Furthermore, ileal digestible lysine also overestimated bioavailable lysine determined using the slope-ratio assay for heated field peas when fed to pigsReference Van Barneveld, Batterham and Norton49. Similar results were found for maize and high-oil maizeReference Parsons, Zhang and Araba54 and autoclaved and non-autoclaved soyabean mealReference Parsons, Hashimoto, Wedekind, Han and Baker98 when fed to poultry. Mavromichalis & BakerReference Mavromichalis and Baker52 reported good agreement between lysine bioavailability, determined using a standard-curve-based method where chick growth was related to lysine intake, and true ileal lysine digestibility for a high-quality complex nursery pig diet. Furthermore, Wang & ParsonsReference Wang and Parsons53 fed chicks maize–soya diets containing a high-quality meat and bone meal formulated based on either the ileal digestible lysine content determined using caecectomised roosters or the bioavailable lysine content determined using a slope-ratio assay. They reported similar feed intake, weight gain and feed conversion ratio for the birds fed the two diets formulated using the two methods.

The slope-ratio assay may accurately predict available lysine content in processed protein sources. However, lysine availability determined using the slope-ratio assay is calculated using the total lysine content of the test diet. When applied to a diet containing a processed protein source where early Maillard products are present, total lysine is an inaccurate measure of lysine content, and lysine availability data generated using the total lysine content of the test diet will also be inaccurate. Furthermore, in the above studies where ileal lysine digestibility was compared with the slope-ratio assay estimates, total lysine, not reactive lysine, digestibility was determined. Consequently, this comparison is fundamentally flawed when applied to processed feedstuffs that contain early Maillard products. In cases where good agreement was obtained between slope-ratio assay data and ileal lysine digestibility data, it may simply highlight the inadequacy of the slope-ratio assay. Data generated using growth-based assays such as the slope-ratio assay tend to be highly variable, often making interpretation difficultReference Hurrell and Carpenter1.

Another problem with the slope-ratio assay is that it does not distinguish between the inevitable catabolic lysine losses of the animal and the lysine used for growth. This can lead to an underestimate of lysine availability in processed feedstuffs. In other words, the slope-ratio assay is a predictor of lysine utilisation rather than lysine availability. Furthermore, utilisation is highly dependent on factors unrelated to the feed protein itself; for example, altering the dietary non-protein energy fraction, the dietary vitamin content or using animals of differing genotype can significantly change the utilisation of dietary amino acidsReference Hodgkinson, Moughan, Moughan, Verstegen and Visser-Reyneveld99. We would argue that inevitable catabolic lysine losses are a function of the animal and not the food or feedstuff and occur not because the lysine has been damaged during processing but rather as a result of normal metabolic function. These losses form part of the animal's natural requirement for lysine and must be accounted for when formulating diets.

Indicator amino acid oxidation technique

Another assay has recently been developed for determining amino acid availability based on the indicator amino acid oxidation techniqueReference Moehn, Bertolo, Pencharz and Ball100. This method can be applied to any amino acid and Moehn et al. Reference Moehn, Bertolo, Pencharz and Ball100 have described a study investigating the availability of lysine. This involved either feeding pigs radioactive phenylalanine or infusing it directly into the bloodstream at the same time as the pig received a test diet formulated to contain lysine at levels which render it the first limiting amino acid. The oxidation of phenylalanine was determined in the pigs fed a test diet and compared with pigs fed control diets for which the lysine content was known, and was also first limiting. Lysine availability was then calculated based on the proportion of phenylalanine oxidation in the pigs fed the test diet compared with that on the control diet. Moehn et al. Reference Moehn, Bertolo, Pencharz and Ball100 tested heated field peas similar to those used by van Barneveld et al. Reference Van Barneveld, Batterham and Norton49 and found good agreement between lysine availability data generated using the isotope amino acid oxidation technique and that determined using the slope-ratio assay. However, given that van Barneveld et al. Reference Van Barneveld, Batterham and Norton49 calculated lysine availability based on the total lysine content of the heated peas then the accuracy of their estimates may be in question. Consequently, Moehn et al. Reference Moehn, Bertolo, Pencharz and Ball100 may be comparing the accuracy of their method against inaccurate estimates of lysine availability. Once again, strictly, the method is based on a measure of utilisation rather than uptake from the digestive tract. In spite of the latter reservations, this method is soundly conceived and appears to have practical application.

The Biolysine™ (digestible reactive lysine) assay

True ileal lysine digestibility is an accurate measure of lysine availability when applied to unheated or minimally processed protein sourcesReference Batterham, Andersen, Baigent, Darnell and Taverner48. However, it is not accurate when applied to processed protein sources that have sustained lysine damage, since total lysine digestibility is being determined rather than reactive lysine digestibility. Total lysine digestibility is not an accurate measure of lysine availability in processed protein sources since total lysine is not an accurate measure of undamaged lysine. In contrast, reactive lysine is an accurate measure of undamaged lysine in a processed protein source. Therefore, by definition, true ileal reactive lysine digestibility is equivalent to lysine availability.

Most chemical methods used for determining reactive lysine are not specific for the side-chain amino group of lysine and will react with the N-terminal amino group of free amino acids or peptides. Consequently, determining reactive lysine in digesta which contains significant amounts of peptides and amino acids has been problematic. In contrast, the guanidination reaction is specific for the ɛ-amino group of lysineReference Kassell and Chow70Reference Klee and Richards72, Reference Moughan and Rutherfurd81, Reference Zhang, Li, Qiao, Wang, Chen and Thacker84Reference Chervenka and Wilcox87. In our laboratory, we have developed the BIOLYSINE™ assay which accurately determines true ileal reactive lysine digestibility (lysine availability) in processed feedstuffs and foods by coupling the guanidination reaction with the true ileal amino acid digestibility assayReference Moughan and Rutherfurd81.

Briefly, the assay involves feeding a test diet to an animal or human subject, digesta are collected from the terminal ileum and the reactive lysine content of both diet and digesta are determined using the guanidination reaction. Whenever digesta have been sampled as opposed to total collection, the reactive lysine content at the terminal ileum is related to dietary intake using an indigestible marker. Apparent ileal reactive lysine digestibility is calculated as the difference between diet amino acid intake and ileal digesta output. Apparent digestibility is adjusted to true digestibility by correcting for endogenous lysine (assumed to be reactive lysine) flow at the terminal ileum.

Demonstrating the accuracy of the Biolysine™ assay

The BIOLYSINE™ assay has undergone rigorous validation. A well-controlled study based on body lysine retention was used to investigate the accuracy of the assayReference Rutherfurd, Moughan and Morel101. Three diets were formulated to be identical except for the protein source. These included two control diets containing enzymically hydrolysed casein (EHC) as the sole protein source and a test diet for which a heated skimmed milk powder was the sole protein source. The EHC was assumed to be completely digested and absorbed and all diets were limiting in lysine and were isoenergetic. One of the EHC diets contained lysine at the same level as the true ileal digestible total lysine content of the heated skimmed milk powder diet determined based on traditional amino acid analysis, while the other EHC diet contained lysine at the same level as the true ileal digestible reactive lysine content of the heated skimmed milk powder diet determined using the new true ileal digestible reactive lysine assay (guanidination). The diets were then fed to growing pigs and body lysine deposition determinedReference Rutherfurd, Moughan and Morel101 (Table 2). There was no significant difference in lysine deposition for the pigs fed the heated skimmed milk powder diet compared with those fed the EHC control diet for which the lysine content was formulated to match the lysine content of the heated skimmed milk powder diet determined using the true ileal digestible reactive lysine content. In contrast, the lysine deposition of the pigs fed the heated skimmed milk powder diet was significantly higher than for the pigs fed the EHC control diet formulated based on the true ileal digestible total lysine content (traditional assay). The experiment elegantly demonstrated the accuracy of the BIOLYSINE™ (true ileal reactive lysine digestibility) assay in predicting lysine availability and available lysine content in processed feedstuffs and the inaccuracy of the traditional ileal digestibility assay that uses traditional amino acid analysis to determine total lysine.

Table 2 Whole-body lysine deposition (g/d) for pigs fed a heated skimmed milk powder-based diet, and two enzymically hydrolysed casein (EHC) control diets (reproduced with permission from Rutherfurd et al. Reference Rutherfurd, Moughan and Morel101; copyright 1997 American Chemical Society) (Least-squares means with their standard errors)

* Mean value was significantly different from that for EHC diet A (P < 0·05).

† EHC diet A was formulated to contain lysine equal to the digestible lysine content of the heated skimmed milk powder determined using the conventional ileal digestibility assay (reactive lysine in heated skimmed milk powder ×  true digestibility of total lysine (determined using conventional methods) for the heated skimmed milk powder).

‡ EHC diet B was formulated to contain lysine equal to the digestible lysine content of the heated skimmed milk powder determined using the new ileal reactive lysine digestibility assay (reactive lysine in heated skimmed milk powder ×  true digestibility of reactive lysine (determined using the new method) for the heated skimmed milk powder).

The BIOLYSINE™ assay was further validated by comparing the available lysine content of heated field peas determined using growth assays (from the late Dr Batterham's laboratory in Wollongbar, NSW, Australia) with that determined using the BIOLYSINE™ (true ileal reactive lysine digestibility) assayReference Rutherfurd and Moughan32, Reference Van Barneveld, Batterham and Norton49 (Fig. 3). There was good agreement between the available lysine content determined using growth assaysReference Van Barneveld, Batterham and Norton49 and that obtained using the BIOLYSINE™ assayReference Rutherfurd and Moughan32, while ileal total lysine digestibility significantly overestimated the available lysine content particularly for the more severely heated peas. This study further demonstrates the accuracy of the BIOLYSINE™ (digestible reactive lysine) assay and the inaccuracy of the ileal total lysine digestibility (conventional assay) for determining available lysine in processed feedstuffs.

Fig. 3 Comparison of available lysine (g/kg) in field peas determined by the digestible reactive lysine assay (□) or growth assayReference Van Barneveld, Batterham and Norton49 (■). Values are means, with their standard errors indicated by vertical bars. (Reproduced with permission from Rutherfurd et al. Reference Rutherfurd, Moughan and van Osch33; copyright 1997 American Chemical Society).

Rutherfurd & MoughanReference Rutherfurd and Moughan32 have also demonstrated the level of disparity between true ileal total lysine and reactive lysine digestibility estimates that can occur in foods as they are progressively heat treated. In this study, we took a skimmed milk powder and autoclaved it for 1–10 min then determined the true ileal digestible reactive and total lysine contents of the heated powdersReference Rutherfurd and Moughan32 (Table 3). There was little difference between true ileal digestible reactive and total lysine contents in the unheated milk powder, demonstrating that the traditional ileal digestibility assay using amino acid analysis is suitable for application with unprocessed protein sources. However, for the skimmed milk powder autoclaved for 10 min, the digestible total lysine overestimated digestible reactive lysine (available lysine) by 100 % and even after only 1 min autoclaving, this overestimation was 12 %.

Table 3 Digestible total lysine and digestible reactive (available) lysine contents (g/kg air-dry weight) for variably heated skimmed milk powder (reproduced with permission from Rutherfurd & MoughanReference Rutherfurd and Moughan32; copyright 1997 American Chemical Society)

*Digestible total lysine was calculated from total lysine digestibility determined using a true ileal amino acid digestibility assay (rat) where conventional amino acid analysis was used to quantify lysine and from total lysine content in the protein source determined using conventional amino acid analysis.

† Digestible reactive lysine was calculated from reactive lysine digestibility determined using a true ileal amino acid digestibility assay (rat) where the guanidination reaction was used to detect reactive lysine in both diet and digesta and the reactive lysine content in the protein source was determined using the guanidination reaction and amino acid analysis.

Application of the Biolysine™ assay

The BIOLYSINE™ assay has been applied to a wide range of processed foods and feedstuffs including animal feedstuffsReference Rutherfurd, Moughan and van Osch33, milk-based productsReference Rutherfurd and Moughan11, Reference Rutherfurd and Moughan30, ‘ready-to-eat’ breakfast cerealsReference Rutherfurd, Torbatinejad and Moughan29 and pet foodsReference Rutherfurd, Markwick-Rutherfurd and Moughan28 (Table 4). For most of these foods and feedstuffs the assay was sufficiently sensitive to detect small differences between the digestible total lysine content and the available lysine content. Indeed, statistically significant differences of as little as 1·2 % (ultra heat-treated milk) are easily detected. However, for many of the processed protein foods and feedstuffs the overestimation of digestible total lysine was far in excess of that observed for ultra heat-treated milk. For all of the samples shown in Table 4, the overestimation ranged from 0 to 143 %, with the average overestimation being 31 %.

Table 4 Digestible total and reactive lysine contents (available lysine) (g/kg) for a range of protein sources*

*Reproduced with permission from Rutherfurd et al. Reference Rutherfurd, Markwick-Rutherfurd and Moughan28, Reference Rutherfurd, Torbatinejad and Moughan29, Reference Rutherfurd, Moughan and van Osch33; copyright 2007, 2006, 1997 American Chemical Society. Reproduced with permission from Rutherfurd & MoughanReference Rutherfurd and Moughan102. Reproduced with permission from Rutherfurd & MoughanReference Rutherfurd and Moughan30; copyright 2005.

† Digestible total lysine was calculated from the true ileal total lysine digestibility determined using the true ileal amino acid digestibility assay (rat) using traditional amino acid analysis to determine the total lysine content of the diets and digesta and from the total lysine content of the protein source also determined using traditional amino acid analysis.

‡ Digestible reactive lysine was calculated from the true ileal reactive lysine digestibility determined using the BIOLYSINE™ assay (rat) using guanidination and amino acid analysis to determine the reactive lysine content of the diets and digesta and from the reactive lysine content of the cereal also determined using guanidination and amino acid analysis.

The BIOLYSINE™ assay has also been used to highlight the high quality of milk-based foodsReference Rutherfurd and Moughan30. Twelve milk-based foods were tested with only one product showing a greater than 10 % difference between digestible total and reactive lysine content. In contrast, the severe effect of processing on lysine that occurs in some foods and feedstuffs has also been demonstrated. Breakfast cereals are perceived to be a healthy balanced high-quality food product. However, when the BIOLYSINE™ assay was applied to twenty ‘ready-to-eat’ breakfast cereals, high levels of lysine damage were detected in most of the twenty cereals testedReference Rutherfurd, Torbatinejad and Moughan29 (Table 4). On average, digestible total lysine was 42 % higher than the digestible reactive (available) lysine content, suggesting the very large amounts of early Maillard product present in the cereals. Similarly, when applied to twenty processed cat foods digestible total lysine overestimated digestible reactive lysine by between 18 and 143 % with an average overestimation of 72 %Reference Rutherfurd, Markwick-Rutherfurd and Moughan28.

The assay has not only been used to assess the available lysine content of the final processed product, but it has also been used to monitor the effect of the manufacturing processing itself on lysine availability. SM Rutherfurd and PJ Moughan (personal communication), using the BIOLYSINE™ assay, found that the lactose hydrolysis process, used to produce low-lactose milk powders, may have a negative impact on available lysine content (Table 5), while the processing method required to manufacture skimmed milk powder had little effect on the available lysine content.

Table 5 Digestible reactive (available) lysine contents (g/kg air-dry weight) of a skimmed milk powder and a hydrolysed lactose skimmed milk powder and the raw milks used to produce the products (reproduced with permission from SM Rutherfurd and PJ Moughan, unpublished results)

The BIOLYSINE™ assay has also been used to assess the shelf life of milk powders by examining the effect of long-term storage on available lysine content of a skimmed milk powder and a lactose hydrolysed skimmed milk powderReference Rutherfurd and Moughan11 (Table 6). The BIOLYSINE™ assay showed that as much as 40 % of the original lysine in the skimmed milk powder was damaged after 9 months storage at 40°C, while for the lactose hydrolysed skimmed milk powder 70 % of the lysine was modified after 6 months storage at 40°C. However, at lower storage temperatures, much less lysine modification was observed.

Table 6 Digestible reactive lysine (available) contents (g/kg air-dry weight) for a skimmed milk powder and a hydrolysed lactose skimmed milk powder stored at 30, 35 and 40°C for varying lengths of time determined using the BIOLYSINE™ assay (reproduced with permission from SM Rutherfurd and PJ Moughan, unpublished results)

Lysine determined using acid hydrolysis overestimates reactive lysine but total lysine digestibility underestimates reactive lysine digestibility – an explanation

It is well known that lysine determined using acid hydrolysis overestimates reactive lysine in processed protein sources and it may be expected that ileal total lysine digestibility would overestimate ileal reactive lysine digestibility. However, this is not the case and total lysine digestibility, determined using acid hydrolysis without guanidination, actually underestimates reactive lysine digestibility in processed protein sources (Fig. 4). In a processed feed or food there may be early and late Maillard products; the late Maillard products do not revert back to lysine during acid hydrolysis. However, a proportion of the early Maillard products do revert back to lysine during acid hydrolysis. Fig. 4 shows a hypothetical processed feedstuff that contains 16 units reactive lysine and 5 units reverted lysine, the sum of which is determined as total lysine (although it should be noted that in practice, reactive lysine plus reverted lysine does not always add up to lysine determined using acid hydrolysis. The reason for this has been discussed earlier). The reactive lysine reflects the undamaged lysine in the feedstuff and the reverted lysine is the lysine that reverts from the early Maillard products during acid hydrolysis. When the feed is eaten the proteins are digested by gut proteases, but because of the modified lysine residues in the protein, and possible other factors, digestion will not be complete. The resulting undigested peptides are called limit peptides. These limit peptides will contain proportionally more damaged lysine than undamaged lysine. Moreover, the limit peptides are absorbed to a lesser degree than the normal products of protein digestion, amino acids and small peptides. This leads to a greater proportion of damaged lysine residues compared with the undamaged residues in the digesta at the terminal ileum compared with that in the food or feedstuff being tested. In the example given in Fig. 4, when the ileal digesta are analysed for reactive and total lysine, we find 3 units reactive lysine and 3 units reverted lysine giving 6 units total lysine. This is quite a different proportion to that found in the original feedstuff (16 units reactive lysine and 5 units reverted lysine). When digestibility is calculated, total lysine (reactive + reverted) digestibility is 71 % while reactive lysine digestibility is 81 %. Overall, total lysine (21 units) overestimates reactive lysine (16 units), while total lysine digestibility (71 %) underestimates reactive lysine digestibility (81 %).

Fig. 4 Calculation of the total lysine and reactive lysine (▒) digestibility in a processed protein source. Total lysine determined using amino acid analysis of processed diets and digesta for an animal fed the processed diet is made up of reactive lysine (the undamaged lysine) and reverted lysine (▓), where reverted lysine is the lysine that reverts from early Maillard products (Amadori compound) to lysine during the acid hydrolysis step of amino acid analysis. Reverted lysine =  total lysine – reactive lysine. Reactive lysine digestibility = (16 – 3)/16 ×  100 = 81 %. Total lysine digestibility = (21 – 6)/21 ×  100 = 71 %.

It might be imagined that since total lysine overestimates reactive lysine in the diet, and total lysine digestibility underestimates reactive lysine digestibility and that digestible lysine is calculated by multiplying the lysine in the diet by ileal lysine digestibility, then there will be no net difference between digestible reactive lysine and digestible total lysine when determined in processed protein sources. However, this is generally not the case and if digestible reactive lysine and digestible total lysine estimates are similar in a processed protein source it is only by coincidence rather than some methodological artifact or real phenomenon. Using Fig. 4 as an example we find that the digestible total lysine, which is 15 units, is clearly not the same as the digestible reactive lysine, which is 13 units.

Conclusion

Accurate determination of the available lysine content of processed foods and feedstuffs is particularly important since lysine is often the first limiting amino acid in diets for intensive livestock and human diets high in cereals and low in meat and milk products. Furthermore, the unique chemistry of lysine makes it difficult to determine lysine accurately in processed foods or feedstuffs. While there are many chemical methods available that allow the assessment of reactive lysine levels in such foods and feedstuffs, there are only a few that permit the determination of bioavailable lysine. These include the slope-ratio assay and other growth-based assays and the indicator amino acid oxidation method. The slope-ratio and other growth-based assays tend to be labour intensive, expensive and highly variable. The BIOLYSINE™ assay offers an accurate and sensitive means to determining available lysine content of processed foods and feedstuffs.

References

1Hurrell, RF & Carpenter, KJ (1981) The estimation of available lysine in foodstuffs after Maillard reactions. Prog Food Nutr Sci 5, 159176.Google ScholarPubMed
2Friedman, M (1996) Food browning and its prevention: an overview. J Agric Food Chem 44, 631653.CrossRefGoogle Scholar
3Finot, PA, Bujard, E, Mottu, F & Mauron, J (1977) Availability of the true Schiff's base of lysine and lactose in milk. In Protein Crosslinking: Nutritional and Medical Consequences, pp. 343364 [Friedman, M, editor]. New York: Plenum.CrossRefGoogle Scholar
4Mills, FD & Hodge, JE (1976) Amadori compounds: vacuum thermolysis of 1-deoxy-1-l-prolino-d-fructose. Carbohyr Res 51, 912.CrossRefGoogle Scholar
5Tressl, R, Wondrak, G, Kersten, E & Rewicki, D (1994) Structure and potential cross-linking reactivity of a new pentose-specific Maillard product. J Agric Food Chem 42, 26922697.CrossRefGoogle Scholar
6Saito, G, Okitani, A, Hayase, F & Kato, H (1986) Characterization of tryptophan derivatives from the reaction of N-α-acetyl-tryptophan with carbonyl compounds. Agric Biol Chem 50, 23152323.Google Scholar
7Friedman, M & Cuq, JL (1988) Chemistry, analysis, nutritional value, and toxicology of tryptophan. A review. J Agric Food Chem 36, 10791093.CrossRefGoogle Scholar
8Konishi, Y, Hayase, F & Kato, H (1994) Novel imidazolone compounds formed by the advanced Maillard reaction of 3-deoxyglucosone and arginine in proteins. Biosci Biotechnol Biochem 58, 19531955.CrossRefGoogle Scholar
9Finot, PA (1990) Metabolism and physiological effects of Maillard reaction products. In The Maillard Reaction in Food Processing, Human Nutrition, and Physiology, pp. 259271 [Finot, PA, Aeschbacher, HU, Hurrell, RF and Liardon, R, editors]. Basel, Switzerland: Birkhauser.CrossRefGoogle Scholar
10Hurrell, RF & Carpenter, KJ (1977) Nutritional significance of cross-linking formation during food processing. In Protein Crosslinking: Nutritional and Medical Consequences, pp. 225238 [Friedman, M, editor]. New York: Plenum.CrossRefGoogle Scholar
11Rutherfurd, SM & Moughan, PJ (2007) Effect of storage on the digestible reactive lysine content of unhydrolysed and hydrolysed milk-based products. J Agric Food Chem (In the Press).Google Scholar
12Franzen, K, Singh, RF & Okos, MR (1990) Kinetics of nonenzymatic browning in dried skim milk. J Food Eng 11, 225239.CrossRefGoogle Scholar
13Hendriks, WH, Emmens, MMA, Trass, B & Pluske, JR (1999) Heat processing changes the protein quality of canned cat foods as measured with a rat bioassay. J Anim Sci 77, 669676.CrossRefGoogle ScholarPubMed
14Hirs, CHW, Stein, WH & Moore, S (1954) The amino acid composition of ribonuclease. J Biol Chem 211, 941950.CrossRefGoogle ScholarPubMed
15Hartkopf, J, Pahlke, C, Lüdeman, G & Erbersdobler, HF (1994) Determination of N ɛ-carboxymethyllysine by a reversed-phase high-performance liquid chromatography method. J Chromatogr 672, 242246.CrossRefGoogle Scholar
16Mauron, J, Mottu, F, Bujard, E & Eggli, RH (1955) The availability of lysine, methionine and tryptophan in condensed milk and milk powder. In vitro digestion studies. Arch Biochem Biophys 59, 433451.CrossRefGoogle ScholarPubMed
17Heyns, K, Heukeshoven, J & Brose, KH (1968) Der Abbau von Fructose-aminosäuren zu N-(2-Furosylmethyl) Aminosäuren: Zwishenprodukte von Bräunungsreaktionen (Degradation of fructose amino acids to N-(2-furoylmethyl)amino acids. Intermediates in browning reactions). Agnew Chem 80, 627.CrossRefGoogle Scholar
18Finot, PA, Bricout, J, Viani, R & Mauron, J (1968) Identification of a new lysine derivative obtained upon hydrolysis of heated milk. Experimentia 24, 10971099.CrossRefGoogle ScholarPubMed
19Finot, PA, Viani, R, Bricout, J & Mauron, J (1969) Detection and identification of pyridosine, a second lysine derivative obtained upon hydrolysis of heated milk. Experimentia 25, 134–135.CrossRefGoogle ScholarPubMed
20Milán-Carillo, J, Gutiérrez-Dorado, R, Perales-Sánchez, JXK, Cuevas-Rodríguez, EO, Ramírez-Wong, B & Reyes-Moreno, C (2006) The optimization of the extrusion process when using maize flour with a modified amino acid profile for making tortillas. Int J Food Sci Technol 41, 727736.CrossRefGoogle Scholar
21Rufián-Henares, JA, Guerra-Hernández, E & García-Villanova, B (2006) Available lysine and fluorescence in heated milk proteins/dextrinomaltose or lactose solutions. Food Chem 98, 685–692.CrossRefGoogle Scholar
22Malec, LS, Llosa, RA, Naranjo, GB & Vigo, MS (2005) Loss of available lysine during processing of different dulche de leche formations. Int J Dairy Technol 58, 164–168.CrossRefGoogle Scholar
23Siskos, I, Zotos, A & Taylor, KDA (2005) The effect of drying, pressure and processing time on the quality of liquid-smoked trout (Salmo gairdnerii) fillets. J Sci Food Agric 85, 20542060.CrossRefGoogle Scholar
24Fernandez-Artigas, P, Garcia-Villanova, B & Guerra-Hernandez, E (1999) Blockage of available lysine at different stages of infant cereal production. J Sci Food Agric 79, 851–854.3.0.CO;2-U>CrossRefGoogle Scholar
25Horvatić, M & Guterman, M (1997) Available lysine content during cereal flake production. J Sci Food Agric 74, 354–358.3.0.CO;2-K>CrossRefGoogle Scholar
26Mao, L-C, Lee, K-H & Erbersbobler, HF (1993) Effects of heat treatment on lysine in soya protein. J Sci Food Agric 62, 307–309.CrossRefGoogle Scholar
27Couch, JR & Thomas, MC (1976) A comparison of chemical methods for the determination of available lysine in various proteins. J Agric Food Chem 24, 943946.CrossRefGoogle ScholarPubMed
28Rutherfurd, SM, Markwick-Rutherfurd, KJ & Moughan, PJ (2007) The digestible reactive lysine content of selected cat foods. J Agric Food Chem 55, 35173522.CrossRefGoogle Scholar
29Rutherfurd, SM, Torbatinejad, NM & Moughan, PJ (2006) Digestible reactive lysine content of selected breakfast cereals. J Agric Food Chem 54, 94539457.CrossRefGoogle Scholar
30Rutherfurd, SM & Moughan, PJ (2005) Digestible reactive lysine in selected milk-based products. J Dairy Sci 88, 40–48.CrossRefGoogle ScholarPubMed
31Torbatinejad, NM, Rutherfurd, SM & Moughan, PJ (2005) Total and reactive lysine contents in selected cereal-based food products. J Agric Food Chem 53, 44544458.CrossRefGoogle ScholarPubMed
32Rutherfurd, SM & Moughan, PJ (1997) Application of a new method for determining digestible reactive lysine to a range of variably heated protein sources. J Agric Food Chem 45, 1582–1586.CrossRefGoogle Scholar
33Rutherfurd, SM, Moughan, PJ & van Osch, L (1997) Digestible reactive lysine in processed feedstuffs – application of a new bioassay. J Agric Food Chem 45, 1189–1194.CrossRefGoogle Scholar
34Hendriks, WH, Moughan, PJ, Boer, H & van der Poel, AFB (1994) Effects of extrusion on the dye-binding, fluorodinitrobenzene-reactive and total lysine content of soyabean meal and peas. Anim Feed Sci Technol 48, 99–109.CrossRefGoogle Scholar
35Vigo, MS, Malec, LS, Gomez, RG & Llosa, RA (1992) Spectrophotometric assay using o-phthaldialdehyde for determination of reactive lysine in dairy products. Food Chem, 363365.CrossRefGoogle Scholar
36Friedman, M, Pang, J & Smith, GA (1984) Ninhydrin-reactive lysine in food proteins. J Food Sci 49, 10–20.CrossRefGoogle Scholar
37Taverner, MR & Farrell, DJ (1981) Availability to pigs of amino acids in cereal grains. Br J Nutr 46, 173180.CrossRefGoogle ScholarPubMed
38Hurrell, RF & Carpenter, KJ (1974) Mechanisms of heat damage in proteins. 4. The reactive lysine content of heat-damaged material as measured in different ways. Br J Nutr 32, 589604.CrossRefGoogle ScholarPubMed
39Roach, AG, Sanderson, P & Williams, DR (1967) Comparison of methods for the determination of available lysine values in animal and vegetable protein sources. J Sci Food Agric 18, 274–278.CrossRefGoogle ScholarPubMed
40Rao, SR, Carter, FL & Frampton, VL (1963) Dermination of available lysine in oilseed meal proteins. Anal Chem 35, 19271930.CrossRefGoogle Scholar
41Desrosiers, T, Savoie, L, Bergeron, G & Parent, G (1989) Estimation of lysine damage in heated whey proteins by furosine determinations in conjunction with the digestion cell technique. J Agric Food Chem 37, 1385–1391.CrossRefGoogle Scholar
42Moughan, PJ, Schrama, J, Skilton, GA & Smith, WC (1989) In-vitro determination of nitrogen digestibility and lysine availability in meat and bone meals and comparison with in-vivo ileal digestibility estimates. J Sci Food Agric 47, 281–292.CrossRefGoogle Scholar
43Henle, T, Walter, H & Klostermeyer, H (1991) Evaluation of the extent of the early Maillard-reaction in milk products by direct measurement of the Amadori-product lactuloselysine. Z Lebensm Unter Forsch 193, 119–122.CrossRefGoogle ScholarPubMed
44Rehman, Z-U (2006) Storage effects on nutritional quality of commonly consumed cereals. Food Chem 92, 53–57.CrossRefGoogle Scholar
45Undi, M, Moshtaghi, SS, Wittenberg, KM & Ingalls, JR (1996) A comparative study on amino acid availability of moist heated canola meal for poultry vs. ruminants. Anim Feed Sci Technol 63, 179186.CrossRefGoogle Scholar
46Moughan, PJ, Gall, MPJ & Rutherfurd, SM (1996) Absorption of lysine and deoxyketosyllysine in an early Maillard browned casein by the growing pig. J Agric Food Chem 44, 15201525.CrossRefGoogle Scholar
47Erbersdobler, HF & Hupe, A (1991) Determination of lysine damage and calculation of lysine bio-availability in several processed foods. Z Ernährungswiss 30, 46–49.CrossRefGoogle ScholarPubMed
48Batterham, ES, Andersen, LM, Baigent, DR, Darnell, RE & Taverner, MR (1990) A comparison of the availability and ileal digestibility of lysine in cottonseed and soya-bean meals for grower/finisher pigs. Br J Nutr 64, 663677.CrossRefGoogle ScholarPubMed
49Van Barneveld, RJ, Batterham, ES & Norton, BW (1994) The effect of heat on amino acids for growing pigs. 3. The availability of lysine from heat-treated field peas (Pisum sativum cultivar Dundale) determined using the slope ratio assay. Br J Nutr 72, 257–275.CrossRefGoogle ScholarPubMed
50Batterham, ES, Lowe, RF, Darnell, RE & Major, EJ (1986) Availability of lysine in meat meal and meat and bone meal and blood meal as determined by the slope-ratio assay with growing pigs, rats and chicks and by chemical techniques. Br J Nutr 55, 427440.CrossRefGoogle ScholarPubMed
51Lumpkins, BS & Batal, AB (2005) The bioavailability of lysine and phosphorus in distillers dried grains with solubles. Poult Sci 84, 581586.CrossRefGoogle ScholarPubMed
52Mavromichalis, I & Baker, DH (2000) Effects of pelleting and storage of a complex nursery pig diet on lysine bioavailability. J Anim Sci 78, 341–347.CrossRefGoogle ScholarPubMed
53Wang, X & Parsons, CM (1998) Dietary meat and bone meal on a total versus a digestible or bioavailable amino acid basis. Poult Sci 77, 10101015.CrossRefGoogle ScholarPubMed
54Parsons, CM, Zhang, Y & Araba, M (1998) Availability of amino acids in high-oil corn. Poult Sci 77, 10161019.CrossRefGoogle ScholarPubMed
55Fernandez, SR & Parsons, CM (1996) Bioavailability of the digestible lysine and valine in cottonseed meal and soybean meal for chicks. Poult Sci 75, 216–223.CrossRefGoogle Scholar
56McDonough, FE, Hitchins, AD, Bodwell, CE & Staples, RS (1989) Bioavailability of lysine in selected foods by rat growth assay. Plant Foods Hum Nutr 69, 67–75.CrossRefGoogle Scholar
57Noll, SL, Waibel, PE & Behrends, BR (1984) Available lysine content of blood meals determined by turkey bioassay and fluorodinitrobenzene assay. Poult Sci 63, 144152.CrossRefGoogle Scholar
58Finot, PA & Hurrell, RF (1985) In vitro methods to predict lysine availability. In Digestibility and Amino Acid Availability in Cereals and Oilseeds, pp. 247258 [Finley, JW and Hopkins, DT, editors]. St Paul, MN: American Association of Cereal Chemists Inc.Google Scholar
59Batterham, ES (1992) Availability and utilization of amino acids for growing pigs. Nutr Res Rev 5, 1–18.CrossRefGoogle ScholarPubMed
60Carpenter, KJ (1960) The estimation of available lysine in animal-protein foods. Biochem J 77, 604610.CrossRefGoogle ScholarPubMed
61Carpenter, KJ, Steinke, FH, Catigani, GL, Swaisgood, HE, Allred, MC, MacDonald, JL & Schelstraete, M (1989) The estimation of “available lysine” in human foods by three chemical procedures. Plant Foods Hum Nutr 39, 129–135.CrossRefGoogle ScholarPubMed
62Rayner, CJ & Fox, M (1978) Measurement of available lysine in processed beef muscle by various laboratory techniques. J Agric Food Chem 26, 494497.CrossRefGoogle Scholar
63Booth, VH (1971) Problems with the determination of FDNB-available lysine. J Sci Food Agric 22, 658666.CrossRefGoogle ScholarPubMed
64Van Barneveld, RJ, Batterham, ES & Norton, BW (1994) The effect of heat on amino acids for growing pigs. 1. A comparison of ileal and faecal digestibilities of amino acids in raw and heat-treated field peas (Pisum sativum cultivar Dundale). Br J Nutr 72, 221–241.CrossRefGoogle ScholarPubMed
65Carpenter, KJ & Bjarnason, J (1968) Nutritional evaluation of proteins by chemical methods. In Evaluation of Novel Protein Products, p. 161 (Bender, AE, Kihlberg, R, Löfqvist, B, Munck, L, editors). Oxford: Pergamon Press.Google Scholar
66Kakade, ML & Leiner, IE (1969) Determination of available lysine in protein. Anal Biochem 27, 273280.CrossRefGoogle Scholar
67Mauron, J & Bujard, E (1964) Guanidination, an alternative approach to the determination of available lysine in foods. Proc 6th Int Nutr Congr, 489490.Google Scholar
68Maga, JA (1971) Measurement of available lysine using the guanidination reaction. J Food Sci 46, 132–134.CrossRefGoogle Scholar
69Hettinger, TP & Harbury, HA (1965) Guanidinated cytochrome c. II. Biochemistry 4, 25852589.CrossRefGoogle ScholarPubMed
70Kassell, B & Chow, RB (1966) Modification of the basic trypsin inhibitor of bovine pancreas. The ɛ-amino groups of lysine and the amino terminal sequence. Biochemistry 5, 34493453.CrossRefGoogle Scholar
71Shields, GS, Hill, RL & Smith, EL (1959) Preparation and properties of guanidinated mercuripapain. J Biol Chem 234, 1747–1753.CrossRefGoogle ScholarPubMed
72Klee, WA & Richards, FM (1957) The reaction of o-methylisourea with bovine pancreatic ribonuclease. J Biol Chem 229, 489–504.CrossRefGoogle ScholarPubMed
73Hughes, WL Jr, Saroff, HA & Carney, AL (1949) Preparation and properties of serum and plasma proteins. XXII. A crystallizable guanidinated derivative of human serum albumin. J Am Chem Soc 71, 24762480.CrossRefGoogle Scholar
74Rutherfurd, SM, Chung, TK & Moughan, PJ (2007) The effect of a commercial enzyme preparation on apparent metabolisable energy, the true ileal amino acid digestibility and endogenous ileal lysine losses in broiler chickens. Poult Sci 86, 665672.CrossRefGoogle Scholar
75Ravindran, V, Hew, LI, Ravindran, G & Bryden, WL (2004) Endogenous amino acid flow in the avian ileum: quantification using three techniques. Br J Nutr 92, 217–223.CrossRefGoogle ScholarPubMed
76Nyachoti, CM, de Lange, CFM & Schulze, H (1997) Estimating endogenous amino acid flows at the terminal ileum and true ileal amino acid digestibilities in feedstuffs for growing pigs using the homoarginine method. J Anim Sci 75, 32063213.CrossRefGoogle ScholarPubMed
77Siriwan, P, Bryden, WL & Annison, EF (1994) Use of guanidinated dietary protein to measure losses of endogenous amino acids in poultry. Br J Nutr 71, 515529.CrossRefGoogle ScholarPubMed
78Moughan, PJ, Darragh, AJ, Smith, WC & Butts, CA (1990) Perchloric and trichloroacetic acids as precipitants of protein in endogenous ileal digesta from the rat. J Sci Food Agric 52, 13–21.CrossRefGoogle Scholar
79Moughan, PJ & Rutherfurd, SM (1990) Endogenous flow of total lysine and other amino acids at the distal ileum of the protein- and peptide-fed rat: the chemical labelling of gelatin protein by transformation of lysine to homoarginine. J Sci Food Agric 52, 179–192.CrossRefGoogle Scholar
80Hagemeister, H & Erbersdobler, H (1985) Chemical labeling of dietary protein by transformation of lysine to homoarginine: a new technique to follow intestinal digestion and absorption. Proc Nutr Soc 44, 133A.Google Scholar
81Moughan, PJ & Rutherfurd, SM (1996) A new method for determining digestible reactive lysine in foods. J Agric Food Chem 44, 22022209.CrossRefGoogle Scholar
82Rutherfurd, SM & Moughan, PJ (1990) Guanidination of lysine in selected dietary proteins. J Agric Food Chem 38, 209211.CrossRefGoogle Scholar
83Möller, AB, Andrews, AT & Cheeseman, GC (1977) Chemical changes in ultra-heat-treated milk during storage III. Methods for the estimation of lysine and sugar-lysine derivatives formed by the Maillard reaction. J Dairy Res 44, 277281.CrossRefGoogle Scholar
84Zhang, HL, Li, DF, Qiao, SY, Wang, FL, Chen, XJ & Thacker, PA (2006) The effect of dietary homoarginine derived from guanidination of synthetic lysine on endogenous amino acid loss and apparent and true ileal amino acid digestibility in the pig. Anim Sci 82, 23–30.CrossRefGoogle Scholar
85Catrein, I, Herrmann, R, Bosserhoff, A & Ruppert, T (2005) Experimental proof for a signal peptidase 1 like activity in Mycoplasma pneumoniae, but absence of a gene encoding a conserved bacterial type 1 SPase. FEBS J 272, 28922900.CrossRefGoogle Scholar
86Yamaguchi, M, Nakazawa, T, Kuyama, H, Obama, T, Ando, E, Okamura, T-A, Ueyama, N & Norioka, S (2005) High-throughput method for N-terminal sequencing of proteins by MALDI mass spectrometry. Anal Chem 77, 645651.CrossRefGoogle ScholarPubMed
87Chervenka, CH & Wilcox, PE (1956) Chemical derivatives of chymotrypsinogen. II Reaction with O-methylisourea. J Biol Chem 222, 635647.CrossRefGoogle ScholarPubMed
88Wang, D, Xu, W, McGrath, SC, Patterson, C, Neckers, L & Cotter, RJ (2005) Direct identification of ubiquitination sites on ubiquitin-conjugated CHIP using MALDI mass spectrometry. J Proteome Res 4, 1554–1560.CrossRefGoogle ScholarPubMed
89Wiseman, J, Jagger, S, Cole, DJA & Haresign, W (1991) The digestion and utilization of amino acids of heat-treated fish meal by growing/finishing pigs. Anim Sci 22, 82–85.Google Scholar
90Moughan, PJ (2003) Amino acid availability: aspects of chemical and bioassay methodology. Nutr Res Rev 16, 127–141.CrossRefGoogle ScholarPubMed
91Hodgkinson, SM & Moughan, PJ (2000) Amino acids – the collection of ileal digesta and characterisation of the endogenous component. In Developments in the Determination of Protein and Amino Acids. Feed Evaluation: Principles and Practice, pp. 105–124 [Moughan, PJ, Verstegen, MWA and Visser-Reyneveld, MI, editors]. Wageningen, the Netherlands: Wageningen Pers.Google Scholar
92Moughan, PJ (1991) Towards an improved utilization of amino acids by the growing pig. In Recent Advances in Animal Nutrition, pp. 45–64 [Haresign, W and Cole, DJA, editors]. Oxford, UK: Butterworth-Heinemann.Google Scholar
93Batterham, ES (1994) Ileal digestibilities of amino acids in feedstuffs for pigs. In Amino Acids in Farm Animal Nutrition, pp. 113131 [D'Mello, JPF, editor]. Wallingford, UK: CAB International.Google Scholar
94Bodwell, CE (1977) Application of animal data to human protein nutrition: a review. Cereal Chem 54, 958983.Google Scholar
95Batterham, ES, Murison, RD & Lewis, CE (1979) Availability of lysine in protein concentrates as determined by the slope-ratio assay with growing pigs and rats and by chemical techniques. Br J Nutr 41, 383391.CrossRefGoogle ScholarPubMed
96Faldet, MA, Satter, LD & Broderick, GA (1992) Determining optimal heat treatment of soybeans by measuring available lysine chemically and biologically with rats to maximize protein utilization by ruminants. J Nutr 122, 151160.CrossRefGoogle ScholarPubMed
97Adeola, O (1996) Bioavailability of tryptophan in soyabean meal for 10-kg pigs using slope ratio assay. J Anim Sci 74, 24112419.CrossRefGoogle ScholarPubMed
98Parsons, CM, Hashimoto, K, Wedekind, KJ, Han, Y & Baker, DH (1992) Effect of overprocessing on availability of amino acids and energy in soybean meal. Poult Sci 71, 133–140.CrossRefGoogle Scholar
99Hodgkinson, SM & Moughan, PJ (2000) Amino acids: digestibility, availability and metabolism. In Developments in the Determination of Protein and Amino Acids. Feed Evaluation: Principles and Practice, pp. 125–132 [Moughan, PJ, Verstegen, MWA and Visser-Reyneveld, MI, editors]. Wageningen, the Netherlands: Wageningen Pers.Google Scholar
100Moehn, S, Bertolo, RFP, Pencharz, PB & Ball, RO (2005) Development of the indicator amino acid oxidation technique to determine the availability of amino acids from dietary protein in pigs. J Nutr 135, 28662870.CrossRefGoogle ScholarPubMed
101Rutherfurd, SM, Moughan, PJ & Morel, PCH (1997) Assessment of the true ileal digestibility of reactive lysine as a predictor of lysine uptake from the small intestine of the growing pig. J Agric Food Chem 45, 43784383.CrossRefGoogle Scholar
102Rutherfurd, SM & Moughan, PJ (1997) Determining reactive lysine and the digestibility of reactive lysine in heat processed foods. Proc Nutr Soc N Z 22, 222234.Google Scholar
Figure 0

Fig. 1 The fate of lysine during processing and analysis. (A) Unprocessed protein source; (B) processed protein source.

Figure 1

Fig. 2 Comparison of the reactive lysine content of (A) selected breakfast cereals (r 0·985 (P < 0·001); y = 1·05x+0·01) and (B) selected animal feedstuffs (blood meal, meat and bone meal, wheat meal, soyabean meal and cottonseed meal (r 0·996 (P < 0·001); y = 1·04x+1·21) determined using either the guanidination reaction or the fluorodinitrobenzene (FDNB) method. (—), Complete agreement between the two methods. (Reproduced with permission from Torbatinejad et al.31 and Rutherfurd et al.33; copyright 2005, 1997 American Chemical Society.)

Figure 2

Table 1 The amount of total lysine, fluorodinitrobenzene (FDNB)-reactive lysine, reactive lysine and absorbed reactive (available) lysine in a heated glucose–casein mixture (reproduced with permission from Moughan et al.46; copyright 1996 American Chemical Society)

Figure 3

Table 2 Whole-body lysine deposition (g/d) for pigs fed a heated skimmed milk powder-based diet, and two enzymically hydrolysed casein (EHC) control diets (reproduced with permission from Rutherfurd et al.101; copyright 1997 American Chemical Society) (Least-squares means with their standard errors)

Figure 4

Fig. 3 Comparison of available lysine (g/kg) in field peas determined by the digestible reactive lysine assay (□) or growth assay49 (■). Values are means, with their standard errors indicated by vertical bars. (Reproduced with permission from Rutherfurd et al.33; copyright 1997 American Chemical Society).

Figure 5

Table 3 Digestible total lysine and digestible reactive (available) lysine contents (g/kg air-dry weight) for variably heated skimmed milk powder (reproduced with permission from Rutherfurd & Moughan32; copyright 1997 American Chemical Society)

Figure 6

Table 4 Digestible total and reactive lysine contents (available lysine) (g/kg) for a range of protein sources*

Figure 7

Table 5 Digestible reactive (available) lysine contents (g/kg air-dry weight) of a skimmed milk powder and a hydrolysed lactose skimmed milk powder and the raw milks used to produce the products (reproduced with permission from SM Rutherfurd and PJ Moughan, unpublished results)

Figure 8

Table 6 Digestible reactive lysine (available) contents (g/kg air-dry weight) for a skimmed milk powder and a hydrolysed lactose skimmed milk powder stored at 30, 35 and 40°C for varying lengths of time determined using the BIOLYSINE™ assay (reproduced with permission from SM Rutherfurd and PJ Moughan, unpublished results)

Figure 9

Fig. 4 Calculation of the total lysine and reactive lysine (▒) digestibility in a processed protein source. Total lysine determined using amino acid analysis of processed diets and digesta for an animal fed the processed diet is made up of reactive lysine (the undamaged lysine) and reverted lysine (▓), where reverted lysine is the lysine that reverts from early Maillard products (Amadori compound) to lysine during the acid hydrolysis step of amino acid analysis. Reverted lysine =  total lysine – reactive lysine. Reactive lysine digestibility = (16 – 3)/16 ×  100 = 81 %. Total lysine digestibility = (21 – 6)/21 ×  100 = 71 %.