Department of Surgery, Maastricht University Medical Centre, NUTRIM, School of Nutrition and Translational Research in Metabolism, Maastricht, the Netherlands.
Department of Clinical Chemistry, University of Liverpool, Liverpool, UK.
Clin Nutr. 2021 May;40(5):2988-2998. doi: 10.1016/j.clnu.2021.02.012. Epub 2021 Feb 17.
In evolution, genes survived that could code for metabolic pathways, promoting long term survival during famines or fasting when suffering from trauma, disease or during physiological growth. This requires utilization of substrates, already present in some form in the body. Carbohydrate stores are limited and to survive long, their utilization is restricted to survival pathways, by inhibiting glucose oxidation and glycogen synthesis. This leads to insulin resistance and spares muscle protein, because being the main supplier of carbon for new glucose production. In these survival pathways, part of the glucose is degraded in glycolysis in peripheral (muscle) tissues to pyruvate and lactate (Warburg effect), which are partly reutilized for glucose formation in liver and kidney, completing the Cori-cycle. Another part of the glucose taken up by muscle contributes, together with muscle derived amino acids, to the production of substrates consisting of a complete amino acid mix but extra non-essential amino acids like glutamine, alanine, glycine and proline. These support cell proliferation, matrix deposition and redox regulation in tissues, specifically active in host response and during growth. In these tissues, also glucose is taken up delivering glycolytic intermediates, that branch off and act as building blocks and produce reducing equivalents. Lactate is also produced and released in the circulation, adding to the lactate released by muscle in the Cori-cycle and completing secondary glucose cycles. Increased fluxes through these cycles lead to modest hyperglycemia and hyperlactatemia in states of healthy growth and disease and are often misinterpreted as induced by hypoxia.
在进化过程中,能够编码代谢途径的基因得以存活,从而在饥荒或创伤、疾病或生理生长期间促进长期生存。这需要利用已经以某种形式存在于体内的底物。碳水化合物储存有限,为了长期生存,其利用受到限制,只能通过抑制葡萄糖氧化和糖原合成来维持生存途径。这导致胰岛素抵抗,并节省肌肉蛋白,因为肌肉是新葡萄糖产生的主要碳源。在这些生存途径中,部分葡萄糖在周围(肌肉)组织中通过糖酵解降解为丙酮酸和乳酸(瓦博格效应),其中一部分在肝和肾中重新用于葡萄糖形成,完成科里循环。肌肉摄取的另一部分葡萄糖与肌肉衍生的氨基酸一起,产生由完整的氨基酸混合物组成的底物,但额外的非必需氨基酸如谷氨酰胺、丙氨酸、甘氨酸和脯氨酸。这些支持组织中的细胞增殖、基质沉积和氧化还原调节,特别是在宿主反应和生长过程中活跃。在这些组织中,葡萄糖也被摄取,提供糖酵解中间产物,这些中间产物分支并作为构建块,并产生还原当量。乳酸也在循环中产生并释放,增加了科里循环中肌肉释放的乳酸,并完成了二级葡萄糖循环。这些循环通量的增加导致健康生长和疾病状态下的适度高血糖和高乳酸血症,并且经常被误解为缺氧诱导的。
