Is branched-chain amino acid nutritional supplementation beneficial or detrimental in heart failure?

Koichi Narita,Eisuke Amiya

Koichi Narita,Eisuke Amiya,Department of Cardiovascular Medicine,The University of Tokyo,Tokyo 113-8655,Japan

Abstract Sarcopenia or cachexia is often complicated in heart failure.Nutritional support,particularly branched-chain amino acid (BCAA) supplementation,is a candidate treatment for improving sarcopenia or cachexia in elderly patients.However,the efficacy of BCAA supplementation in patients with heart failure has not been established,and the issue is comparatively more complex.Indeed,there are conflicting reports on the efficacy of BCAA supplementation.The evidence for including BCAA supplementation in treating patients with heart failure was reviewed,and the complexity of the issue was discussed.

Key Words:Branched-chain amino acid;Heart failure;Sarcopenia;Cachexia;Nutrition;Branched-chain a-ketoacids

INTRODUCTION

Sarcopenia or cachexia is often complicated in heart failure,which aggravates the clinical course of the disease.Sarcopenia and cachexia were reported to be present in approximately 20% of patients with heart failure;however,there were differences in their percentages among different studies[1].Also,both of them sometimes coexist in approximately 10% of patients with heart failure[2].Low physical performance and reduced cardiopulmonary capacity influence sarcopenia and cachexia[3].These comorbidities are independent predictors of the clinical course of patients with heart failure[4].Therefore,the therapeutic strategy for sarcopenia or cachexia is a critical issue in managing heart failure.However,there is no standard management strategy at this time.

Nutritional support might be one candidate treatment for the improvement of sarcopenia or cachexia.Amino acid supplementation was effective for sarcopenia in elderly patients.Rondanelliet al[5] demonstrated nutritional supplementation with whey protein,essential amino acids,and vitamin D for twelve weeks,significantly increasing fat-free mass and muscle strength.Among several amino acid supplementation types,branched-chain amino acids (BCAAs) were beneficial in forming skeletal muscles because they account for a large part of the essential amino acids that form these skeletal muscles[6].Ottestadet al[7] reported that BCAA levels decreased by 10% in sarcopenic adults,whereas nonessential amino acid levels did not change,suggesting the importance of BCAAs in skeletal muscle maintenance.

BENEFICIAL EFFECT OF BCAA IN PATIENTS WITH HEART FAILURE

Several reports about BCAA’s effect on cardiopulmonary performance in other populations exist (Table 1).Changet al[8] demonstrated that BCAA and arginine supplementation improved performance in intermittent sprints by reducing perceived exertion.Other reports on experimental and clinical conditions,according to the effect of improvement in exercise capacity by BCAA supplementation,were also presented[9-11].Additionally,BCAA supplementation also reduced the muscle damage associated with endurance exercise[12].Therefore,BCAA supplementation might have favorable effects on improving and maintaining exercise capacity,which might help patients with heart failure and reduced exercise capacity.Furthermore,several reports about the efficacy of BCAA supplementation for the improvement of sarcopenia also exist.Koet al[13] demonstrated that BCAA administration for five weeks improved several parameters,including bioelectrical-impedance-analysis-derived skeletal mass index by approximately 10% and grip strength by about 10%.BCAA supplementation before and after exercise has shown beneficial effects in decreasing exercise-induced muscle damage and promoting muscle-protein synthesis[14].Leucine supplementation also enhances myofibrillar protein synthesis,leading to increased muscle strength[15,16].These effects could be partly explained by the shift to anabolic signaling of the skeletal muscle through the mammalian target of rapamycin complex 1 pathway[17].Indeed,the anabolic pathway decreased because of alterations in the insulin-like growth factor 1/growth hormone axis and increased catabolism,induced by proinflammatory cytokines,in the presence of heart failure with sarcopenia[18].There were several reports of the impact of BCAA on the treatment of sarcopenia.

Table 1 Outcomes of branched-chain amino acid administration in clinical trials

Nicholset al[19] performed a systematic review of the effect of amino acid supplementation in heart failure.They demonstrated that essential amino acid supplementation could improve important outcome measures related to sarcopenia.For instance,amino acid supplementation increased the six-minute walk test distance by approximately 20%.In contrast,few reports demonstrated BCAA efficacy in the improvement of heart failure[20,21].Oral intake of AAs is presumed to improve exercise capacities through its beneficial effect on the skeletal muscle in patients with heart failure.Furthermore,BCAA treatment decreased the heart rate,preserved cardiac function,and prolonged survival in heart failure with reduced ejection fraction model rats[20].Uchinoet al[21] reported that in-hospital heart failure patients with hypoalbuminemia showed increased serum albumin,decreased cardiothoracic ratio(CTR),and increased cholinesterase after BCAA supplementation.Another beneficial effect of BCAA is that it activates rapamycin’s mammalian target (mTOR),promoting albumin synthesis[22].The increase in serum albumin might favorably affect the clinical course of heart failure.The improvement in CTR could be due to decongestion efficiently induced by BCAA administration.

DETRIMENTAL EFFECT OF BCAA IN PATIENTS WITH HEART FAILURE

A clinical trial on the efficacy of BCAA supplementation in cardiac rehabilitation was conducted[23].However,the issue might be more complex.Conversely,there are reports of BCAA’s pathological role in heart failure.In clinical studies,several reports about the link between the high level of circulating BCAA and the risk of cardiovascular diseases,including heart failure,are present[24-27].For instance,in the study of type 2 diabetes patients free of cardiovascular and renal diseases,patients with incident heart failure had 5.6% higher serum BCAAs than those without heart failure(HF).Serum BCAAs had a positive linear association with incident HF,adjusting for age,sex,and duration of diabetes.They demonstrated that high levels of BCAA corresponded to the increased event risk of atherosclerotic diseases and heart failure.Recent studies reported that BCAA catabolism is impaired in a failing heart,downregulating catabolic enzyme expression[28,29].This catabolic derangement increases the levels of BCAAs and branched-chain a-ketoacids (BCKAs),which reportedly have a direct effect on cardiac remodeling and dysfunction through mTOR activation and reactive oxygen production (Figure 1)[30].In basic experiments,incubation with BCKAs led to decreased cell survival and increased apoptosis in primary cardiomyocytes[31].Moreover,increased BCAA concentration in the heart was shown to suppress glucose metabolism,enhancing ischemia-reperfusion injury by enhancing the GCN2/ATF6/PPAR-α pathway[32].BCKA dehydrogenase (BCKD) activity,a critical step in BCAA catabolism,is regulated by the phosphorylation of regulatory subunit E1a.BCKD kinase (BCKDK) phosphorylates E1a to inhibit BCKA dehydrogenase activity,increasing BCKDK expression in defective hearts[33].From these findings,the additional increase of BCAA through BCAA supplementation might exacerbate BCAA metabolites’ burden in a failed heart,worsening the clinical course further in heart failure.

Figure 1 Branched-chain amino acid and its catabolic pathway in patients with heart failure.

By contrast,some hopeful hints about the BCAA metabolic pathway in heart failure therapy might exist.In BCKDK regulation,3,6-dichlorobenzo[b]thiophene-2-carboxylic acid (BT2),a small-molecule BCKDK inhibitor,blocks BCKD phosphorylation,leading to increased BCAA catabolism[34].Moreover,BT2 might alleviate oxidative stress by reducing BCKA or mTOR complex 1 activity by lowering BCAA concentrations,thereby improving cardiac function[35].A study of BT2 administration to mice suggested that BT2 treatment improved cardiac function and led to remodeling without apparent toxicity[34].

The transcriptional factor Kruppel-like factor 15 (KLF15) also has a critical role in cardiac BCAA catabolic regulation[28].KLF15-deficient hearts displayed reduced BCAT2 expression,another critical step in BCAA catabolism,whereas intramyocardial BCKA levels were elevated in KLF15-null hearts.KLF15 is reportedly a direct transcriptional activator of BCAT2[36].KLF15 expression is lower in human cardiomyopathy.Therefore,the loss of KLF15 is a critical molecular mechanism underlying stress-induced BCAA catabolic defects in the diseased heart[37,38].The modification of the KLF15 pathway could help the diseased heart in the BCAA metabolic pathway;however,its overexpression evoked arrhythmia due to its regulatory role in the potassium channel[39].

Additionally,the mitochondrial matrix-targeted 2C-type ser/thr protein phosphatase 2C family member (PP2Cm) is the endogenous phosphatase of the BCKD and functions as a key regulator of BCAA catabolism and homeostasis.The PP2Cm expression in the heart is dynamically regulated in the failing heart[40].A study on PP2Cm-deficient mice revealed that PP2Cm deficiency led to heart failure signs,including weight gain,reduced left ventricular ejection fraction (LVEF),and chamber dilation[30].The study findings suggested the impact of BCAA metabolism on the pathogenesis of heart failure.Furthermore,BT2 overturned the dysfunction induced in PP2Cm-knockout mice,significantly preserved LVEF,and reduced chamber dilation.The efficacy of BT2 treatment for the reinforcement of the BCAA metabolic pathway might be more than expected for the dysfunctional heart[41].These basic findings would present some hints for treating heart failure,which is associated with the BCAA pathway.

CONCLUSION

Studies have shown that BCAAs are beneficial in heart failure.Conversely,BCAAs could act as exacerbators of heart failure.Nevertheless,improving BCAA metabolism might lead to an effective treatment strategy for the disease.In conclusion,the pros and cons of BCAA supplementation could vary depending on the patient and their specific conditions.Particularly,BCAA supplementation for patients with cardiac dysfunction,who could easily be presumed to have metabolic dysfunction,should be carefully considered.