Vascular endothelial dysfunction has been associated with various CVD risk factors, including hypertension(Reference Ghiadoni, Huang and Magagna1), and is considered an early event in the development of atherosclerosis. Elevated blood pressure (BP) represents a major independent risk factor for CVD(Reference Kannel and Higgins2) and is commonly treated pharmacologically by inhibiting angiotensin-converting enzyme (ACE). As ACE is a key enzyme in the regulation of BP, inhibition of its activity prevents the production of the vasoconstrictor angiotensin II from its precursor angiotensin I and removes ACE-mediated inactivation of the vasodilatory molecule bradykinin. Several clinical studies have shown improvement in vascular function in patients prescribed ACE inhibitors(Reference Tousoulis, Antoniades and Koumallos3), potentially a result of the pleiotropic effects of ACE inhibitors on the vascular endothelium(Reference Faggiotto and Paoletti4). Unfortunately, several adverse reactions associated with ACE inhibitors have been reported (i.e. hypotension, cough, fatigue), necessitating the need for alternative therapies.
Increasing interest in the prevention of CVD through the consumption of bioactive dietary compounds as an alternative to pharmacological therapy has led to the discovery of several food-derived peptides possessing ACE-inhibitory activity(Reference De Leo, Panarese and Gallerani5). Milk is one such example that serves as a rich source of bioactive peptides, including ACE-inhibitory peptides(Reference FitzGerald and Meisel6), which have been shown to exert a wide range of biological actions including decreased BP(Reference Erdmann, Cheung and Schroder7, Reference FitzGerald, Murray and Walsh8) and improved vascular function(Reference Hirota, Ohki and Kawagishi9). The release of these biologically active peptide fragments results from enzymatic hydrolysis occurring either during gastrointestinal digestion or during milk fermentation(Reference Teschemacher, Koch and Brantl10). Whey proteins comprise about 20 % of total milk proteins and have a high prevalence of essential amino acids, particularly leucine. The main whey protein constituents in bovine milk are β-lactoglobulin and α-lactalbumin(Reference Fox11). The efficient metabolism of whey protein is thought to be a result of its unique heterogeneous group of proteins and a high content of branched-chain amino acids(Reference Layman12). Specifically, in vitro and in vivo studies have demonstrated ACE-inhibitory activity of the tripeptides isoleucine-proline-proline (Ile-Pro-Pro) and valine-proline-proline (Val-Pro-Pro) isolated from fermented milk(Reference Masuda, Nakamura and Takano13, Reference Nakamura, Yamamoto and Sakai14). In addition, Sipola et al. (Reference Sipola, Finckenberg and Vapaatalo15) investigated the dilatory response of rat superior mesenteric arteries incubated with α-lactorphin (Tyr-Gly-Leu-Phe) and β-lactorphin (Tyr-Leu-Leu-Phe), which are released by enzymatic hydrolysis from the whey proteins α-lactalbumin and β-lactoglobulin, respectively. In preparations obtained from hypertensive rats, incubation with both tetrapeptides improved endothelium-dependent relaxation, an effect abolished by inhibiting NO synthase. In addition, endothelium-independent dilation in hypertensive rats was enhanced in the presence of β-lactorphin, but not in the presence of α-lactorphin. These data suggest that peptides derived from whey proteins have the potential to improve hypertension-induced vascular dysfunction through ACE inhibition and/or NO- and non-NO-mediated pathways.
Promising in vitro data have led to investigations seeking to examine the effect of whey proteins on BP and/or vascular function in humans(Reference Kawase, Hashimoto and Hosoda16–Reference Pal and Ellis18). Investigations that have determined the beneficial effects of chronic whey consumption on BP and vascular function(Reference Kawase, Hashimoto and Hosoda16, Reference Pal and Ellis18) in humans have fostered further studies seeking to elucidate whether these beneficial effects can be observed during the acute postprandial period. Recent evidence highlights the importance of the postprandial period as a contributing factor to chronic disease, such as diabetes and atherosclerosis(Reference Alipour, Elte and van Zaanen19, Reference Sies, Stahl and Sevanian20). Thus, dietary interventions that potentially mitigate the metabolic disturbances that occur during the postprandial period (i.e. hyperglycaemia, hypertriacylglycerolaemia) are of great interest in an attempt to restore biological homeostasis. Indeed, a single dose of whey protein was demonstrated to decrease the appearance of plasma TAG and glucose following a breakfast meal in overweight women(Reference Pal, Ellis and Ho21). Furthermore, as adverse cardiovascular events peak in the early morning hours after waking(Reference Muller, Stone and Turi22), perhaps due to an increase in BP or blunting of flow-mediated dilation(Reference Hirsch, Shechter and Feinberg23), dietary interventions that acutely improve cardiovascular function may be beneficial during this period of increased risk. The measurement of NO-dependent vascular function via conduit artery flow-mediated dilation(Reference Joannides, Haefeli and Linder24) independently predicts adverse cardiovascular events in healthy subjects(Reference Hirsch, Shechter and Feinberg23). Therefore, further identification of the impact that whey proteins may acutely exert on the cardiovascular system has both practical and clinical implications.
In this issue of the British Journal of Nutrition, Pal & Ellis(Reference Pal and Ellis25) provide insight into this uncertainty by assessing the acute impact of a whey protein isolate on BP, arterial stiffness and inflammatory markers in postmenopausal women, a population particularly susceptible to the development of CVD. Postprandial measurements were taken intermittently for 6 h following consumption of a breakfast meal in conjunction with one of three supplements: 45 g whey protein isolate, 45 g sodium caseinate or a 45 g glucose control. Despite significant time effects over the course of the 6 h postprandial period, there were no significant differences in BP, arterial stiffness or inflammatory markers between the three groups. The lack of acute effects on cardiovascular measures in this study suggests that the beneficial effects demonstrated previously with whey protein result from habitual intake. Only one other study has investigated the acute cardiovascular effects of a peptide derived from whey protein(Reference Ballard, Bruno and Seip26). This study non-invasively assessed vascular function before and serially for 2 h following ingestion of 5 g of a hydrolysed peptide derived from whey in young, healthy men and women. Compared with placebo (artificially sweetened water), ingestion of a beverage containing the whey-derived peptide significantly increased brachial artery flow-mediated dilation for up to 90 min postprandially. Furthermore, reactive hyperaemia forearm blood flow, a response primarily independent of NO formation(Reference Tagawa, Imaizumi and Endo27), increased at 120 min postprandially. These findings suggest that acute ingestion of this whey-derived peptide enhanced vascular function via mechanisms both dependent and independent of NO production. Ongoing work from our laboratory is attempting to determine the effect of this particular whey extract on ageing-induced vascular dysfunction. In addition to its vascular effects, acute whey protein ingestion has the potential to suppress appetite(Reference Pal and Ellis28) and increase protein synthesis following exercise(Reference Tang, Moore and Kujbida29).
Nutraceuticals hold promise as an adjunct or alternative to pharmaceutical treatment of CVD. Emerging research indicates that whey proteins possess a wide range of biological effects that include improvement in CVD risk factors such as hypertension and vascular dysfunction. Future research is needed to further elucidate the potential health benefits and possible underlying mechanisms (i.e. NO production, ACE inhibition) to acute and chronic whey protein ingestion, particularly in individuals at an increased risk of CVD (i.e. hypertensives, aged, overweight), to identify the unique components of whey responsible and to determine the differing effects of intact and hydrolysed whey proteins. Continued investigation into the potential cardiovascular benefits of acute whey protein ingestion, particularly following a postprandial challenge or as a potential dietary therapy to attenuate early morning cardiovascular events, is warranted.
There is no conflict of interest.
Vascular endothelial dysfunction has been associated with various CVD risk factors, including hypertension(Reference Ghiadoni, Huang and Magagna1), and is considered an early event in the development of atherosclerosis. Elevated blood pressure (BP) represents a major independent risk factor for CVD(Reference Kannel and Higgins2) and is commonly treated pharmacologically by inhibiting angiotensin-converting enzyme (ACE). As ACE is a key enzyme in the regulation of BP, inhibition of its activity prevents the production of the vasoconstrictor angiotensin II from its precursor angiotensin I and removes ACE-mediated inactivation of the vasodilatory molecule bradykinin. Several clinical studies have shown improvement in vascular function in patients prescribed ACE inhibitors(Reference Tousoulis, Antoniades and Koumallos3), potentially a result of the pleiotropic effects of ACE inhibitors on the vascular endothelium(Reference Faggiotto and Paoletti4). Unfortunately, several adverse reactions associated with ACE inhibitors have been reported (i.e. hypotension, cough, fatigue), necessitating the need for alternative therapies.
Increasing interest in the prevention of CVD through the consumption of bioactive dietary compounds as an alternative to pharmacological therapy has led to the discovery of several food-derived peptides possessing ACE-inhibitory activity(Reference De Leo, Panarese and Gallerani5). Milk is one such example that serves as a rich source of bioactive peptides, including ACE-inhibitory peptides(Reference FitzGerald and Meisel6), which have been shown to exert a wide range of biological actions including decreased BP(Reference Erdmann, Cheung and Schroder7, Reference FitzGerald, Murray and Walsh8) and improved vascular function(Reference Hirota, Ohki and Kawagishi9). The release of these biologically active peptide fragments results from enzymatic hydrolysis occurring either during gastrointestinal digestion or during milk fermentation(Reference Teschemacher, Koch and Brantl10). Whey proteins comprise about 20 % of total milk proteins and have a high prevalence of essential amino acids, particularly leucine. The main whey protein constituents in bovine milk are β-lactoglobulin and α-lactalbumin(Reference Fox11). The efficient metabolism of whey protein is thought to be a result of its unique heterogeneous group of proteins and a high content of branched-chain amino acids(Reference Layman12). Specifically, in vitro and in vivo studies have demonstrated ACE-inhibitory activity of the tripeptides isoleucine-proline-proline (Ile-Pro-Pro) and valine-proline-proline (Val-Pro-Pro) isolated from fermented milk(Reference Masuda, Nakamura and Takano13, Reference Nakamura, Yamamoto and Sakai14). In addition, Sipola et al. (Reference Sipola, Finckenberg and Vapaatalo15) investigated the dilatory response of rat superior mesenteric arteries incubated with α-lactorphin (Tyr-Gly-Leu-Phe) and β-lactorphin (Tyr-Leu-Leu-Phe), which are released by enzymatic hydrolysis from the whey proteins α-lactalbumin and β-lactoglobulin, respectively. In preparations obtained from hypertensive rats, incubation with both tetrapeptides improved endothelium-dependent relaxation, an effect abolished by inhibiting NO synthase. In addition, endothelium-independent dilation in hypertensive rats was enhanced in the presence of β-lactorphin, but not in the presence of α-lactorphin. These data suggest that peptides derived from whey proteins have the potential to improve hypertension-induced vascular dysfunction through ACE inhibition and/or NO- and non-NO-mediated pathways.
Promising in vitro data have led to investigations seeking to examine the effect of whey proteins on BP and/or vascular function in humans(Reference Kawase, Hashimoto and Hosoda16–Reference Pal and Ellis18). Investigations that have determined the beneficial effects of chronic whey consumption on BP and vascular function(Reference Kawase, Hashimoto and Hosoda16, Reference Pal and Ellis18) in humans have fostered further studies seeking to elucidate whether these beneficial effects can be observed during the acute postprandial period. Recent evidence highlights the importance of the postprandial period as a contributing factor to chronic disease, such as diabetes and atherosclerosis(Reference Alipour, Elte and van Zaanen19, Reference Sies, Stahl and Sevanian20). Thus, dietary interventions that potentially mitigate the metabolic disturbances that occur during the postprandial period (i.e. hyperglycaemia, hypertriacylglycerolaemia) are of great interest in an attempt to restore biological homeostasis. Indeed, a single dose of whey protein was demonstrated to decrease the appearance of plasma TAG and glucose following a breakfast meal in overweight women(Reference Pal, Ellis and Ho21). Furthermore, as adverse cardiovascular events peak in the early morning hours after waking(Reference Muller, Stone and Turi22), perhaps due to an increase in BP or blunting of flow-mediated dilation(Reference Hirsch, Shechter and Feinberg23), dietary interventions that acutely improve cardiovascular function may be beneficial during this period of increased risk. The measurement of NO-dependent vascular function via conduit artery flow-mediated dilation(Reference Joannides, Haefeli and Linder24) independently predicts adverse cardiovascular events in healthy subjects(Reference Hirsch, Shechter and Feinberg23). Therefore, further identification of the impact that whey proteins may acutely exert on the cardiovascular system has both practical and clinical implications.
In this issue of the British Journal of Nutrition, Pal & Ellis(Reference Pal and Ellis25) provide insight into this uncertainty by assessing the acute impact of a whey protein isolate on BP, arterial stiffness and inflammatory markers in postmenopausal women, a population particularly susceptible to the development of CVD. Postprandial measurements were taken intermittently for 6 h following consumption of a breakfast meal in conjunction with one of three supplements: 45 g whey protein isolate, 45 g sodium caseinate or a 45 g glucose control. Despite significant time effects over the course of the 6 h postprandial period, there were no significant differences in BP, arterial stiffness or inflammatory markers between the three groups. The lack of acute effects on cardiovascular measures in this study suggests that the beneficial effects demonstrated previously with whey protein result from habitual intake. Only one other study has investigated the acute cardiovascular effects of a peptide derived from whey protein(Reference Ballard, Bruno and Seip26). This study non-invasively assessed vascular function before and serially for 2 h following ingestion of 5 g of a hydrolysed peptide derived from whey in young, healthy men and women. Compared with placebo (artificially sweetened water), ingestion of a beverage containing the whey-derived peptide significantly increased brachial artery flow-mediated dilation for up to 90 min postprandially. Furthermore, reactive hyperaemia forearm blood flow, a response primarily independent of NO formation(Reference Tagawa, Imaizumi and Endo27), increased at 120 min postprandially. These findings suggest that acute ingestion of this whey-derived peptide enhanced vascular function via mechanisms both dependent and independent of NO production. Ongoing work from our laboratory is attempting to determine the effect of this particular whey extract on ageing-induced vascular dysfunction. In addition to its vascular effects, acute whey protein ingestion has the potential to suppress appetite(Reference Pal and Ellis28) and increase protein synthesis following exercise(Reference Tang, Moore and Kujbida29).
Nutraceuticals hold promise as an adjunct or alternative to pharmaceutical treatment of CVD. Emerging research indicates that whey proteins possess a wide range of biological effects that include improvement in CVD risk factors such as hypertension and vascular dysfunction. Future research is needed to further elucidate the potential health benefits and possible underlying mechanisms (i.e. NO production, ACE inhibition) to acute and chronic whey protein ingestion, particularly in individuals at an increased risk of CVD (i.e. hypertensives, aged, overweight), to identify the unique components of whey responsible and to determine the differing effects of intact and hydrolysed whey proteins. Continued investigation into the potential cardiovascular benefits of acute whey protein ingestion, particularly following a postprandial challenge or as a potential dietary therapy to attenuate early morning cardiovascular events, is warranted.
There is no conflict of interest.