Laboratory Medicine, University Medical Center Groningen (UMCG), The Netherlands.
Med Hypotheses. 2011 Jun;76(6):794-801. doi: 10.1016/j.mehy.2011.02.020. Epub 2011 Mar 8.
Perinatal changes in maternal glucose and lipid fluxes and de novo lipogenesis (DNL) are driven by hormones and nutrients. Docosahexaenoic acid (DHA) reduces, whereas insulin augments, nuclear abundance of sterol-regulatory-element-binding-protein-1 (SREBP-1), which promotes DNL, stearoyl-CoA-desaturase (SCD, also Δ9-desaturase), fatty acid-(FA)-elongation (Elovl) and FA-desaturation (FADS). Decreasing maternal insulin sensitivity with advancing gestation and compensatory hyperinsulinemia cause augmented postprandial glucose levels, adipose tissue lipolysis and hepatic glucose- and VLDL-production. Hepatic VLDL is composed of dietary, body store and DNL derived FA. Decreasing insulin sensitivity increases the contribution of FA from hepatic-DNL in VLDL-triacylglycerols, and consequently saturated-FA and monounsaturated-FA (MUFA) in maternal serum lipids increase during pregnancy. Although other authors described changes in maternal serum and RBC essential-FA (EFA) after delivery, none went into detail about the changes in non-EFA and the mechanisms behind -and/or functions of- the observed changes.
Postpartum FA-changes result from changing enzymatic activities that are influenced by the changing hormonal milieu after delivery and DHA-status.
We studied FA-profiles and FA-ratios (as indices for enzymatic activities) of maternal and infant RBC at delivery and after 3 months exclusive breastfeeding in three populations with increasing freshwater-fish intakes. DNL-, SCD- and FADS2-activities decreased after delivery. Elongation-6 (Elovl-6)- and FADS1-activities increased. The most pronounced postpartum changes for mothers were increases in 18:0, linoleic (LA), arachidonic acid (AA) and decreases in 16:0, 18:1ω9 and DHA; and for infants increases in 18:1ω9, 22:5ω3, LA and decreases in 16:0 and AA. Changes were in line with the literature.
Postpartum increases in 18:0, and decreases in 16:0 and 18:1ω9, might derive from reduced insulin-promoted DNL-activity, with more reduced SCD- than Elovl-activity that leaves more 16:0 to be converted to 18:0 (Elovl-activity) than to MUFA (SCD-activity). Postpartum changes in ΣDNL, saturated-FA and MUFA related negatively to RBC-DHA. This concurs with suppression of both SCD- and Elovl-6 activities by DHA, through its influence on SREBP. Infant MUFA and LA increased at expense of their mothers. Sustained transport might be important for myelination (MUFA) and skin barrier development (LA). Maternal postpartum decreases in FADS2-, and apparent increases in FADS1-activity, together with increases in LA, AA, and 22:5ω3, but decrease in DHA, confirm that FADS2 is rate limiting in EFA-desaturation. Maternal LA and AA increases might be the result of rerouting from transplacental transfer to the incorporation into milk lipids and discontinued placental AA-utilization.
Perinatal changes in maternal and infant FA status may be strongly driven by changing insulin sensitivity and DHA status.
围产期母体葡萄糖和脂质通量以及从头合成(DNL)的变化是由激素和营养物质驱动的。二十二碳六烯酸(DHA)减少,而胰岛素增加核固醇调节元件结合蛋白-1(SREBP-1)的丰度,这促进了 DNL、硬脂酰辅酶 A 去饱和酶(SCD,也称为 Δ9 去饱和酶)、脂肪酸-(FA)伸长(Elovl)和 FA 去饱和(FADS)。随着妊娠的进展,母体胰岛素敏感性降低和代偿性高胰岛素血症导致餐后血糖水平升高、脂肪组织脂肪分解和肝葡萄糖和 VLDL 生成增加。肝 VLDL 由膳食、体脂储存和 DNL 衍生的 FA 组成。胰岛素敏感性降低增加了 VLDL 三酰甘油中来自肝-DNL 的 FA 贡献,因此母体血清脂质中的饱和 FA 和单不饱和 FA(MUFA)在妊娠期间增加。尽管其他作者描述了分娩后母体血清和 RBC 必需脂肪酸(EFA)的变化,但没有人详细描述非 EFA 的变化以及观察到的变化背后的机制-和/或功能。
产后 FA 的变化是由于产后激素环境变化和 DHA 状况影响了酶活性的变化。
我们研究了三个鱼类摄入量逐渐增加的人群中母亲和婴儿 RBC 在分娩时和 3 个月纯母乳喂养后的 FA 谱和 FA 比(作为酶活性的指标)。DNL、SCD 和 FADS2 活性在分娩后下降。Elongation-6(Elovl-6)和 FADS1 活性增加。母亲最明显的产后变化是 18:0 增加,亚油酸(LA)、花生四烯酸(AA)减少,16:0、18:1ω9 和 DHA 减少;婴儿的 18:1ω9、22:5ω3、LA 增加,16:0 和 AA 减少。这些变化与文献一致。
产后 18:0 的增加和 16:0 和 18:1ω9 的减少可能源于胰岛素促进的 DNL 活性降低,SCD 活性比 Elovl 活性降低更多,这使得更多的 16:0 转化为 18:0(Elovl 活性)而不是 MUFA(SCD 活性)。产后 ΣDNL、饱和 FA 和 MUFA 的变化与 RBC-DHA 呈负相关。这与 DHA 通过其对 SREBP 的影响抑制 SCD 和 Elovl-6 活性一致。婴儿的 MUFA 和 LA 增加以牺牲母亲的 MUFA 和 LA 为代价。持续的转运可能对髓鞘形成(MUFA)和皮肤屏障发育(LA)很重要。母亲产后 FADS2 活性下降,FADS1 活性似乎增加,同时 LA、AA 和 22:5ω3 增加,而 DHA 减少,证实 FADS2 是 EFA 去饱和的限速酶。母亲 LA 和 AA 的增加可能是由于从胎盘转移到乳脂的再分配以及停止胎盘 AA 利用的结果。
母体和婴儿 FA 状态的围产期变化可能主要受胰岛素敏感性和 DHA 状态的变化驱动。
