Department of Cancer Biology, University of Pennsylvania, Philadelphia, PA 19104, USA; Abramson Family Cancer Research Institute, University of Pennsylvania, Philadelphia, PA 19104, USA; Center for Metabolic Disease Research, Department of Microbiology and Immunology, Lewis Katz School of Medicine, Temple University, Philadelphia, PA 19140, USA.
Department of Cancer Biology, University of Pennsylvania, Philadelphia, PA 19104, USA; Abramson Family Cancer Research Institute, University of Pennsylvania, Philadelphia, PA 19104, USA.
Mol Metab. 2020 Aug;38:100941. doi: 10.1016/j.molmet.2020.01.005. Epub 2020 Feb 14.
Many metabolites serve as important signalling molecules to adjust cellular activities and functions based on nutrient availability. Links between acetyl-CoA metabolism, histone lysine acetylation, and gene expression have been documented and studied over the past decade. In recent years, several additional acyl modifications to histone lysine residues have been identified, which depend on acyl-coenzyme A thioesters (acyl-CoAs) as acyl donors. Acyl-CoAs are intermediates of multiple distinct metabolic pathways, and substantial evidence has emerged that histone acylation is metabolically sensitive. Nevertheless, the metabolic sources of acyl-CoAs used for chromatin modification in most cases remain poorly understood. Elucidating how these diverse chemical modifications are coupled to and regulated by cellular metabolism is important in deciphering their functional significance.
In this article, we review the metabolic pathways that produce acyl-CoAs, as well as emerging evidence for functional roles of diverse acyl-CoAs in chromatin regulation. Because acetyl-CoA has been extensively reviewed elsewhere, we will focus on four other acyl-CoA metabolites integral to major metabolic pathways that are also known to modify histones: succinyl-CoA, propionyl-CoA, crotonoyl-CoA, and butyryl-CoA. We also briefly mention several other acyl-CoA species, which present opportunities for further research; malonyl-CoA, glutaryl-CoA, 3-hydroxybutyryl-CoA, 2-hydroxyisobutyryl-CoA, and lactyl-CoA. Each acyl-CoA species has distinct roles in metabolism, indicating the potential to report shifts in the metabolic status of the cell. For each metabolite, we consider the metabolic pathways in which it participates and the nutrient sources from which it is derived, the compartmentalisation of its metabolism, and the factors reported to influence its abundance and potential nuclear availability. We also highlight reported biological functions of these metabolically-linked acylation marks. Finally, we aim to illuminate key questions in acyl-CoA metabolism as they relate to the control of chromatin modification.
A majority of acyl-CoA species are annotated to mitochondrial metabolic processes. Since acyl-CoAs are not known to be directly transported across mitochondrial membranes, they must be synthesized outside of mitochondria and potentially within the nucleus to participate in chromatin regulation. Thus, subcellular metabolic compartmentalisation likely plays a key role in the regulation of histone acylation. Metabolite tracing in combination with targeting of relevant enzymes and transporters will help to map the metabolic pathways that connect acyl-CoA metabolism to chromatin modification. The specific function of each acyl-CoA may be determined in part by biochemical properties that affect its propensity for enzymatic versus non-enzymatic protein modification, as well as the various enzymes that can add, remove and bind each modification. Further, competitive and inhibitory effects of different acyl-CoA species on these enzymes make determining the relative abundance of acyl-CoA species in specific contexts important to understand the regulation of chromatin acylation. An improved and more nuanced understanding of metabolic regulation of chromatin and its roles in physiological and disease-related processes will emerge as these questions are answered.
许多代谢物作为重要的信号分子,根据营养物质的可用性来调节细胞活动和功能。过去十年中,已经记录并研究了乙酰辅酶 A 代谢、组蛋白赖氨酸乙酰化和基因表达之间的联系。近年来,已经鉴定出组蛋白赖氨酸残基的几种额外的酰基修饰,这些修饰依赖于酰基辅酶 A 硫酯(酰基辅酶 A)作为酰基供体。酰基辅酶 A 是多种不同代谢途径的中间产物,大量证据表明组蛋白酰化对代谢敏感。然而,在大多数情况下,用于染色质修饰的酰基辅酶 A 的代谢来源仍知之甚少。阐明这些不同的化学修饰如何与细胞代谢偶联并受其调节,对于破译它们的功能意义很重要。
在本文中,我们综述了产生酰基辅酶 A 的代谢途径,以及各种酰基辅酶 A 在染色质调节中的功能作用的新证据。由于乙酰辅酶 A 在其他地方已经被广泛综述,我们将重点介绍另外四种与主要代谢途径相关的酰基辅酶 A 代谢物,这些代谢物也已知可修饰组蛋白:琥珀酰辅酶 A、丙酰辅酶 A、巴豆酰辅酶 A 和丁酰辅酶 A。我们还简要提到了其他几种酰基辅酶 A 物质,它们为进一步研究提供了机会;丙二酰辅酶 A、戊二酰辅酶 A、3-羟基丁酰辅酶 A、2-羟基异丁酰辅酶 A 和乳酰辅酶 A。每种酰基辅酶 A 物质在代谢中都有独特的作用,表明有可能报告细胞代谢状态的变化。对于每种代谢物,我们考虑其参与的代谢途径以及其来源的营养物质,其代谢的区室化,以及报告影响其丰度和潜在核可用性的因素。我们还强调了这些与代谢相关的酰化标记的报道生物学功能。最后,我们旨在阐明与染色质修饰控制有关的酰基辅酶 A 代谢中的关键问题。
大多数酰基辅酶 A 物质都被注释为线粒体代谢过程。由于酰基辅酶 A 据知不能直接穿过线粒体膜运输,它们必须在体外合成,可能在核内合成,以参与染色质调节。因此,亚细胞代谢区室化可能在组蛋白酰化的调节中起着关键作用。代谢物追踪与相关酶和转运蛋白的靶向相结合,将有助于绘制连接酰基辅酶 A 代谢与染色质修饰的代谢途径。每种酰基辅酶 A 的特定功能可能部分取决于影响其酶促和非酶促蛋白修饰倾向的生化特性,以及可以添加、去除和结合每种修饰的各种酶。此外,不同酰基辅酶 A 物质对这些酶的竞争和抑制作用使得确定特定情况下酰基辅酶 A 物质的相对丰度对于理解染色质酰化的调节很重要。随着这些问题的回答,对染色质代谢及其在生理和疾病相关过程中的作用的代谢调节的理解将更加完善和细致。
