The organization of metabolic multienzyme complexes has been hypothesized to benefit metabolic processes and provide a coordinated way for the cell to regulate metabolism. Historically, their existence has been supported by various in vitro techniques. However, it is only recently that the existence of metabolic complexes inside living cells has come to light to corroborate this long-standing hypothesis. Indeed, subcellular compartmentalization of metabolic enzymes appears to be widespread and highly regulated. On the other hand, it is still challenging to demonstrate the functional significance of these enzyme complexes in the context of the cellular milieu. In this review, we discuss the current understanding of metabolic enzyme complexes by primarily focusing on central carbon metabolism and closely associated metabolic pathways in a variety of organisms, as well as their regulation and functional contributions to cells.

Dynamic partitioning of de novo purine biosynthetic enzymes into multienzyme compartments, purinosomes, has been associated with increased flux of de novo purine biosynthesis in human cells. However, we do not know of a mechanism by which de novo purine biosynthesis would be downregulated in cells. We have investigated the functional role of AMP-activated protein kinase (AMPK) in the regulation of de novo purine biosynthesis because of its regulatory action on lipid and carbohydrate biosynthetic pathways. Using pharmacological AMPK activators, we have monitored subcellular localizations of six pathway enzymes tagged with green fluorescent proteins under time-lapse fluorescence single-cell microscopy. We revealed that only one out of six pathway enzymes, formylglycinamidine ribonucleotide synthase (FGAMS), formed spatially distinct cytoplasmic granules after treatment with AMPK activators, indicating the formation of single-enzyme self-assemblies. In addition, subsequent biophysical studies using fluorescence recovery after photobleaching showed that the diffusion kinetics of FGAMS were slower when it localized inside the self-assemblies than within the purinosomes. Importantly, high-performance liquid chromatographic studies revealed that the formation of AMPK-promoted FGAMS self-assembly caused the reduction of purine metabolites in HeLa cells, indicating the downregulation of de novo purine biosynthesis. Collectively, we demonstrate here that the spatial sequestration of FGAMS by AMPK is a mechanism by which de novo purine biosynthesis is downregulated in human cells.

•Fluorescence single-cell microscopy is a promising technique for in-cell enzymology.•Subcellular imaging strategies with genetically-encoded proteins in live cells•Imaging-based strategies for monitoring protein–protein interactions in living cells•Spatiotemporal measurement of protein activities in living cells.A cell is a highly organized, dynamic, and intricate biological entity orchestrated by a myriad of proteins and their self-assemblies. Because a protein's actions depend on its coordination in both space and time, our curiosity about protein functions has extended from the test tube into the intracellular space of the cell. Accordingly, modern technological developments and advances in enzymology have been geared towards analyzing protein functions within intact single cells. We discuss here how fluorescence single-cell microscopy has been employed to identify subcellular locations of proteins, detect reversible protein–protein interactions, and measure protein activity and kinetics in living cells. Considering that fluorescence single-cell microscopy has been only recently recognized as a primary technique in enzymology, its potentials and outcomes in studying intracellular protein functions are projected to be immensely useful and enlightening. We anticipate that this review would inspire many investigators to study their proteins of interest beyond the conventional boundary of specific disciplines. This article is part of a Special Issue entitled: Physiological Enzymology and Protein Functions.

Enzymes in human de novo purine biosynthesis have been demonstrated to form a reversible, transient multienzyme complex, the purinosome, upon purine starvation. However, characterization of purinosomes has been limited to HeLa cells and has heavily relied on qualitative examination of their subcellular localization and reversibility under wide-field fluorescence microscopy. Quantitative approaches, which are particularly compatible with human disease-relevant cell lines, are necessary to explicitly understand the purinosome in live cells. In this work, human breast carcinoma Hs578T cells have been utilized to demonstrate the preferential utilization of the purinosome under purine-depleted conditions. In addition, we have employed a confocal microscopy-based biophysical technique, fluorescence recovery after photobleaching, to characterize kinetic properties of the purinosome in live Hs578T cells. Quantitative characterization of the diffusion coefficients of all de novo purine biosynthetic enzymes reveals the significant reduction of their mobile kinetics upon purinosome formation, the dynamic partitioning of each enzyme into the purinosome, and the existence of three intermediate species in purinosome assembly under purine starvation. We also demonstrate that the diffusion coefficient of the purine salvage enzyme, hypoxanthine phosphoribosyltransferase 1, is not sensitive to purine starvation, indicating exclusion of the salvage pathway from the purinosome. Furthermore, our biophysical characterization of nonmetabolic enzymes clarifies that purinosomes are spatiotemporally different cellular bodies from stress granules and cytoplasmic protein aggregates in both Hs578T and HeLa cells. Collectively, quantitative analyses of the purinosome in Hs578T cells led us to provide novel insights for the dynamic architecture of the purinosome assembly.