Effect of diets and chronic intermittent hypoxia on the fatty acid composition in serum and heart lipids

In agreement with other studies⁽Reference Stubbs and Smith¹⁷⁾, we confirmed that the n-6:n-3 PUFA ratio in all serum and heart lipids was shifted in favour of the predominant PUFA class in the diet. CIH induced a decrease of the n-6:n-3 PUFA ratio due to the 22 : 6n-3 enrichment at the expense of 20 : 4n-6 in all heart lipids, independent of the diet. This effect was the most consistent in heart PL. Whereas the (SFA+MUFA):PUFA ratio in serum and heart TAG and DAG reflected the ratio of the corresponding diet, in serum PL and CE and heart PL it was kept relatively constant regardless of dietary interventions or CIH.

The primary role of TAG is the transport of fatty acids into tissues providing a store of energy. In the present study, fatty acid profiles of serum and heart TAG closely followed those of the diets in line with the fact that samples were collected from fed rats, i.e. chylomicrons were the predominant form of circulating TAG-rich lipoproteins. It is generally accepted that fatty acids derived from the hydrolysis of TAG-rich chylomicrons may be the primary source of fatty acids utilised by the heart, particularly in the fed state⁽Reference Augustus, Kako and Yagyu¹⁸⁾.

CE represent the transport form of cholesterol in the blood that is supplied to the heart, which has low cholesterol biosynthetic capacity⁽Reference Spady and Dietschy¹⁹⁾. The present results show that nearly a half of the overall fatty acid content in CE of the lard and maize oil groups comprises 20 : 4n-6 while in the fish oil group this PUFA is replaced to a large extent by 20 : 5n-3. It has been reported that 20 : 5n-3 is the preferred substrate both for lysophosphatidylcholine acyltransferase, leading to the formation of phosphatidylcholine in the rat liver⁽Reference Iritani and Fujikawa²⁰⁾, and for plasma lecithin:cholesterol acyltransferase which transfers PUFA from plasma phosphatidylcholine to CE⁽Reference Holub, Bakker and Skaeff²¹⁾. This may explain the partial replacement of 20 : 4n-6 with 20 : 5n-3 in plasma CE of the fish oil dietary group in agreement with results of Garg et al. ⁽Reference Garg, Wierzbicki and Thomson²²⁾. CIH further increased the incorporation of 20 : 5n-3 into CE of the fish oil group, probably due to the enhanced supply of 20 : 5n-3 from serum PL (i.e. phosphatidylcholine).

Serum and heart PL contained substantially higher proportions of 18 : 0 and 20 : 4n-6 than the diets. It has been reported that a large proportion of 18 : 0 and 20 : 4n-6 is incorporated into PL due to the preferential affinity of acyltransferases and transacylases for these fatty acids during the fatty acid remodelling process associated with PL de novo synthesis in the rat liver⁽Reference Yamashita, Sugiura and Waku²³⁾. In the fish oil group, 20 : 5n-3 was preferentially incorporated into serum PL and CE whereas the accumulation of 22 : 6n-3 was favoured in all heart lipids despite nearly equimolar proportions of these two n-3 PUFA in the diet. The preferential incorporation of 22 : 6n-3 into myocardial lipids has been reported in other studies on rodents⁽Reference Rousseau, Héliès-Toussaint and Moreau²⁴⁾ and human subjects⁽Reference Metcalf, James and Gibson²⁵⁾. CIH increased the accumulation of 22 : 6n-3 at the expense of 20 : 4n-6 in myocardial PL of the lard and maize oil groups. However, in the fish oil group, CIH stimulated the accumulation of 22 : 6n-3 in heart PL at the expense of 18 : 2n-6 without any compensatory effect on 20 : 4n-6. It is evident that CIH-adapted myocardium tends to preserve the relatively low level of 20 : 4n-6 in PL that was already reduced by the fish oil diet.

The shifts in the n-6 and n-3 PUFA proportions in heart PL caused by diets and CIH were qualitatively similar to those observed in rats fed different PUFA-enriched diets and chronically treated with high doses of catecholamines⁽Reference Benediktsdottir and Gudbjarnason²⁶⁾. In line with this observation, exposure of rats to CIH was associated with transiently increased adrenergic activity and elevated plasma levels of catecholamines⁽Reference Maher, Manchanda and Cymerman^27, Reference Ostadal, Kvetnansky, Prochazka, Usdin, Kvetnansky and Kopin²⁸⁾. Thus, the fatty acid remodelling in PL induced by CIH could be explained by stress-dependent hormonal modulation of enzyme activities involved in PL acyl remodelling. PL deacylation was accelerated due to the activation of phospholipase A2 in cardiomyocytes exposed to hypoxia⁽Reference Kawaguchi, Shoki and Iizuka^29, Reference Grynberg, Nalbone and Degois³⁰⁾. It is likely that this enzyme which preferentially hydrolyses 20 : 4n-6 from the sn2 position of membrane PL⁽Reference Nalbone, Grynberg and Chevalier³¹⁾ and acyl-CoA synthase with preferential affinity for 22 : 6n-3⁽Reference Bouroudian, Nalbone and Grynberg³²⁾ could contribute to the 22 : 6n-3 accumulation in heart PL by the deacylation–reacylation cycle observed after CIH.

Our observation that DAG comprised a high proportion of SFA and MUFA but a low proportion of PUFA as compared with other lipids regardless of dietary interventions is in agreement with several reports⁽Reference Hamplova, Novakova and Tvrzicka^33–Reference Eskildsen-Helmond, Hahnel and Reinhardt³⁶⁾. The fish oil diet increased the 22 : 6n-3 proportion in DAG compared with other diets. This observation is in line with the results obtained in fish oil-supplemented mice and dogs⁽Reference Takahashi, Okumura and Asai^37, Reference Judé, Martel and Vincent³⁸⁾. DAG are important endogenous lipid activators of PKC⁽Reference Nishizuka³⁹⁾. Besides a direct interaction of this lipid with PKC, changes induced in the membrane lipid structure by DAG and other lipids favour the binding and activation of PKC⁽Reference Goñi and Alonso⁴⁰⁾. It has been shown that DAG enriched with 20 : 5n-3 or 22 : 6n-3 were less efficient activators of PKC than DAG containing 20 : 4n-6⁽Reference Madani, Hichami and Legrand⁴¹⁾. Judé et al. ⁽Reference Judé, Martel and Vincent³⁸⁾ observed a lower activation of PKC δ and PKC ɛ in the hearts of fish oil-supplemented dogs than in those fed the standard diet. In line with the results mentioned above, Hlavackova et al. demonstrated a lower abundance of PKC δ in the particulate fraction from normoxic hearts of rats fed the fish oil diet, together with the larger myocardial infarct size compared with the maize oil dietary group⁽Reference Hlavackova, Neckar and Jezkova¹⁰⁾. On the other hand, adaptation to CIH that further increased the 22 : 6n-3 proportion in heart DAG of the fish oil group stimulated the expression of PKC δ and had a protective effect on infarct size. These results suggest that the impact of changes in the PUFA composition of DAG on PKC activation or inactivation in connection with cardiac ischaemic tolerance is complex and may differ in normoxic and chronically hypoxic hearts. CIH also increased 20 : 4n-6 in DAG of the maize oil group and tended to increase it in the lard and fish oil groups in contrast with heart TAG and PL where 20 : 4n-6 either decreased or remained unchanged. The fact that CIH specifically increased the accumulation of 20 : 4n-6 in myocardial phosphatidylcholine⁽Reference Jezkova, Novakova and Kolar⁹⁾ offers the explanation that phosphatidylcholine could be an important source of DAG under the CIH conditions. In accordance with this assumption, it has been reported that DAG generated from phosphatidylcholine by phospholipase D is involved in ischaemic preconditioning⁽Reference Cohen, Liu and Liu^42, Reference Tosaki, Maulik and Cordis⁴³⁾. Murase et al. ⁽Reference Murase, Okumura and Hayashi³⁵⁾ found an increased DAG content as well as an increased proportion of 20 : 4n-6 in DAG of preconditioned rat hearts, supporting the involvement of this signalling lipid in the cardioprotection.

There is a general consensus that n-3 PUFA, particularly 20 : 5n-3 and 22 : 6n-3, exert powerful anti-arrhythmic effects⁽Reference Leaf, Kang and Xiao⁴⁴⁾ resulting from their multiple actions. It was shown, for example, that both 20 : 5n-3 and 22 : 6n-3 decreased cardiac susceptibility to adrenergic stimulation⁽Reference Ponsard, Durot and Delerive⁴⁵⁾, prevented disturbances of membrane transport and ionic homeostasis⁽Reference Pepe and McLennan^46, Reference Rinaldi, Di Pierro and Vitelli⁴⁷⁾, decreased phosphoinositides production⁽Reference Anderson, Du and Sinclair⁴⁸⁾, altered the fatty acid composition of DAG and led to differential PKC activation⁽Reference Judé, Martel and Vincent³⁸⁾. Therefore, the enrichment of 20 : 5n-3 and 22 : 6n-3 in serum and heart lipids demonstrated in the present study could contribute to the anti-arrhythmic effect of CIH observed under ischaemia–reperfusion conditions that was most pronounced in the fish oil group⁽Reference Hlavackova, Neckar and Jezkova¹⁰⁾.

Effect of diets and chronic intermittent hypoxia on myocardial redox status

The increased level of conjugated dienes in the myocardium of fish oil-supplemented rats is in agreement with the increased susceptibility of n-3 PUFA to oxidative stress, compared with the n-6 PUFA class, probably due to the greater presence of double bonds⁽Reference Scislowski, Bauchart and Gruffat⁴⁹⁾. Conjugated dienes are one of the primary metabolic intermediate products of lipoperoxidation⁽Reference Corongiu and Banni^50, Reference Hendra, Wickens and Dormandy⁵¹⁾. Our finding of increased levels of conjugated dienes in the myocardium of the fish oil dietary group corresponds to the largest myocardial infarct size observed in these animals. On the other hand, the same fish oil group exhibited the lowest incidence and severity of ventricular arrhythmias⁽Reference Hlavackova, Neckar and Jezkova¹⁰⁾. This is in line with the suggestion of Judé et al. ⁽Reference Judé, Bedut and Roger⁵²⁾ that an oxidation product of 22 : 6n-3 could effectively protect against arrhythmias rather than 22 : 6n-3 itself.

Despite the increased formation of conjugated dienes in the fish oil group, we did not notice any change in the activities of SOD, GPX or catalase. Likewise, Nageswari et al. ⁽Reference Nageswari, Banerjee and Menon⁵³⁾ did not observe any effect of a fish oil diet on antioxidative enzyme activities in rat hearts despite the increased level of hydroperoxides. In contrast, Diniz et al. ⁽Reference Diniz, Cicogna and Padovani⁵⁴⁾ have shown that both n-3 and n-6 PUFA diets decreased the activities of SOD and catalase and increased the activity of GPX in rat hearts. Under similar experimental conditions, a decrease in activities of myocardial SOD and GPX was detected in another study⁽Reference Schimke, Haberland and Wirth⁵⁵⁾. This inconsistency of available data regarding the effects of lipid dietary supplementation may be due to the variability of experimental models, fatty acid composition of diets and their intake level.

Recently we demonstrated that CIH was associated with increased oxidative stress as evidenced by decreased myocardial reduced:oxidised glutathione ratio and elevated concentration of lipofuscin-like pigments⁽Reference Kolar, Jezkova and Balkova⁸⁾. The present study did not detect any significant effect of CIH on the myocardial level of conjugated dienes in any dietary group. This can be explained by the fact that these compounds are one of the first temporarily detectable unstable markers of lipoperoxidation. It seems likely that changes in the level of conjugated dienes could have appeared at earlier stages of hypoxic adaptation. CIH increased the activity of catalase in the hearts of the fish oil and maize oil groups as compared with the lard-fed group. This suggests that oxidative stress associated with CIH was probably higher in both PUFA dietary groups than in the lard group. In line with our observation, CIH enhanced the activity of catalase in the hearts of rats kept on a standard diet⁽Reference Zhu, Dong and Ding⁵⁶⁾. On the other hand, myocardial activities of catalase and GPX did not differ between normoxic and chronically hypoxic young rats whereas the SOD activity was decreased in the hypoxic group⁽Reference Oka, Itoi and Terada⁵⁷⁾. Although total SOD and GPX remained unchanged in the myocardial homogenate of CIH animals, we cannot exclude that their activities increased in specific subcellular compartments, such as mitochondria, that are involved in reactive oxygen species generation.

We conclude that both dietary interventions as well as CIH had systemic effects leading to distinct changes in the fatty acid profile in serum and heart lipids. In particular, membrane PL maintained SFA, MUFA and total PUFA proportions constant independently of diet and CIH. This is the evidence of a remarkable regulatory ability of membranes to maintain a stable milieu that is necessary for a proper function of membrane proteins. On the other hand, the n-6:n-3 PUFA ratio was influenced to various extents by either the dietary PUFA supply or CIH in all lipid classes. These changes may affect myocardial adaptive responses under various physiological and pathophysiological conditions, such as those associated with ischaemia–reperfusion and oxidative stress.