Karl H. Weisgraber

Apolipoprotein E: Structure-Function Relationships

Publisher Summary This chapter focuses on the role of apoE in lipoprotein metabolism and the most completely described function of the protein. Apolipoprotein E (apoE) is one of the best characterized in terms of its structural and functional properties. Plasma apolipoproteins regulate lipoprotein metabolism and control the transport and redistribution of lipids among tissues and cells. Apolipoproteins can perform one of three major roles because of their ability to bind lipid. First, apolipoproteins stabilize the pseudomicellar structure of lipoprotein particles. Second, apolipoproteins can act as cofactors or activators of various enzymes or lipid transfer proteins that participate in the metabolism of “remodeling” of lipoproteins as they circulate in plasma. A third function of plasma apolipoproteins-one that is restricted to apoB100 and ApoE- is to serve as a ligand for cell surface lipoprotein receptors. The three-dimensional structure of a 22-kDa fragment of human apoE is solved by X-ray crystallography; the relation of this structure to the role of apoE in lipoprotein metabolism is discussed, together with a critical and extensive examination of the chemistry and biology of this apolipoprotein, which plays such a central role in lipoprotein metabolism. Apolipoprotein E has three major isoform in the human population, which affect lipoprotein metabolism differently, resulting in different levels of the plasma lipoproteins. The role of apoE as a cofactor in lipolytic processing of triglyceride-rich lipoproteins, and the role of apoE in the reverse cholesterol transport process are described.

Human apolipoprotein E: the Alzheimer's disease connection.

Human apolipoprotein (apo) E, long known for its prominent role in cholesterol transport and plasma lipoprotein metabolism, has recently emerged as a major genetic risk factor for Alzheimers disease, a neurodegenerative disorder. In a variety of populations worldwide, one of the three common alleles of apoE, apoE4, is overrepresented in Alzheimers subjects compared with age‐ and sex‐ matched controls. The genetic and epidemiologic evidence suggests that apoE is a major susceptibility gene for Alzheimers disease; it likely accounts for a major portion of the genetic heterogeneity in the disease. Although its role in the development of Alzheimers disease is unknown, biochemical and cell biology studies are providing important insights into how apoE may be involved in neurodegenerative disorders. Based on an understanding of the structure and function of apoE in lipid transport and cellular metabolism, it is suggested that apoE is involved in a final common pathway of neuronal repair and remodeling: apoE3 (most common allele) supporting effective repair and remodeling after neuronal injury by noxious agents, and apoE4 being less effective in these processes.—Weisgraber, K. H., Mahley, R. W. Human apolipoprotein E: The Alzheimers disease connection FASEB J. 10, 1485‐1494 (1996)

Altered Metabolism (In Vivo and In Vitro) of Plasma Lipoproteins after Selective Chemical Modification of Lysine Residues of the Apoproteins

Chemical modification of lysine residues by acetoacetylation of the apoproteins of iodinated canine and human low density lipoproteins (LDL) and canine high density lipoproteins (HDL) resulted in a marked acceleration in the rate of removal of these lipoproteins from the plasma after intravenous injection into dogs. Clearance of the lipoproteins from the plasma correlated with their rapid appearance in the liver. Acetoacetylated canine (125)I-LDL (30-60% of the lysine residues modified) were essentially completely removed from the plasma within an hour, and > 75% of the activity cleared within 5 min. Reversal of the acetoacetylation of the lysine residues of the LDL restored to these lipoproteins a rate of clearance essentially identical to that of control LDL. Identical results were obtained with modified human LDL injected into dogs. At 10 min, when congruent with 90% of the acetoacetylated human (125)I-LDL had been removed from the plasma, 90% of the total injected activity could be accounted for in the liver. Furthermore, it was possible to demonstrate an enhancement in uptake and degradation of acetoacetylated LDL by canine peritoneal macrophages in vitro. The mechanism(s) responsible for the enhanced removal of the LDL and HDL in vivo and in vitro remains to be determined. By contrast, however, acetoacetylation of canine (125)I-apoE HDL(c) did not accelerate their rate of removal from the plasma but, in fact, retarded their clearance. Control (native) apoE HDL(c) were removed from the plasma (64% within 20 min) and rapidly appeared in the liver (39% at 20 min). At the same time point, only 45% of the acetoacetylated apoE HDL(c) were cleared from the plasma and <10% appeared in the liver. Acetoacetylation of the apoE HDL(c) did not enhance their uptake or degradation by macrophages. The rapid clearance from the plasma of the native apoE HDL(c) in normal and hypercholesterolemic dogs suggests that the liver may be a normal site for the removal of the cholesteryl ester-rich apoE HDL(c). The retardation in removal after acetoacetylation of apoE HDL(c) indicates that the uptake process may be mediated by a lysine-dependent recognition system.

Human Apolipoprotein E4 Domain Interaction ARGININE 61 AND GLUTAMIC ACID 255 INTERACT TO DIRECT THE PREFERENCE FOR VERY LOW DENSITY LIPOPROTEINS

Human apolipoprotein (apo) E contains an amino- and a carboxyl-terminal domain, which are connected by a hinge region (approximately residues 165 to 215). The interaction of the two domains has been suggested to be responsible for the apoE4-binding preference for very low density lipoproteins (VLDL). In the absence of this interaction in apoE3, the preference is for high density lipoproteins (HDL). To exclude the possibility that the interaction of apoE with other apolipoproteins on the native particles may contribute to the isoform-specific preferences, VLDL-like emulsion particles were incubated with apoE, and the lipid-bound apoE was separated from free apoE on a Superose 6 column. The apoE4 bound more effectively to these particles than did apoE3, indicating that the apoE4 preference for VLDL is due not to interactions with other apolipoproteins but to an intrinsic property of apoE4, likely related to domain interaction. Previously, arginine 61 was shown to be critical for the isoform preferences, suggesting that it interacted with an acidic residue(s) in the carboxyl terminus. Substitution of arginine 61 with lysine did not alter the preference of apoE4 for VLDL, demonstrating that a positive charge rather than a specific requirement for arginine is critical for domain interaction. To identify the acidic residue(s) in the carboxyl terminus interacting with arginine 61, the six acidic residues (244, 245, 255, 266, 270, and 271) in a region known to be important for both lipoprotein association and isoform-specific preferences were substituted individually with alanine in apoE4. Only substitution of glutamic acid 255 altered the preference of apoE4 from VLDL to HDL, indicating that this was the sole residue in the carboxyl terminus that interacts with arginine 61. The participation of the hinge region in domain interaction was examined with internal deletion mutants. Deletion of the residues 186-202 or 186-223, representing major portions of the hinge region, had no effect on the apoE4 preference for VLDL. This suggests that the hinge region may act as a spacer that connects the two domains. Further deletion into the carboxyl-terminal domain (to residue 244) results in a loss of apoE4 VLDL binding. These studies establish that interaction of arginine 61 and glutamic acid 255 mediates apoE4 domain interaction.

Carboxyl-terminal-truncated apolipoprotein E4 causes Alzheimer's disease-like neurodegeneration and behavioral deficits in transgenic mice

Apolipoprotein (apo) E4 increases the risk and accelerates the onset of Alzheimers disease (AD). However, the underlying mechanisms remain to be determined. We previously found that apoE undergoes proteolytic cleavage in AD brains and in cultured neuronal cells, resulting in the accumulation of carboxyl-terminal-truncated fragments of apoE that are neurotoxic. Here we show that this fragmentation is caused by proteolysis of apoE by a chymotrypsin-like serine protease that cleaves apoE4 more efficiently than apoE3. Transgenic mice expressing the carboxyl-terminal-cleaved product, apoE4(Δ272–299), at high levels in the brain died at 2–4 months of age. The cortex and hippocampus of these mice displayed AD-like neurodegenerative alterations, including abnormally phosphorylated tau (p-tau) and Gallyas silver-positive neurons that contained cytosolic straight filaments with diameters of 15–20 nm, resembling preneurofibrillary tangles. Transgenic mice expressing lower levels of the truncated apoE4 survived longer but showed impaired learning and memory at 6–7 months of age. Thus, carboxyl-terminal-truncated fragments of apoE4, which occur in AD brains, are sufficient to elicit AD-like neurodegeneration and behavioral deficits in vivo. Inhibiting their formation might inhibit apoE4-associated neuronal deficits.

Two independent lipoprotein receptors on hepatic membranes of dog, swine, and man. Apo-B,E and apo-E receptors.

We have reported previously that canine livers possess two distinct lipoprotein receptors, an apoprotein (apo)-B,E receptor capable of binding the apo-B-containing low density lipoproteins (LDL) and the apo-E-containing cholesterol-induced high density lipoproteins (HDLc), and an apo-E receptor capable of binding apo-E HDLc but not LDL. Both the apo-B,E and apo-E receptors were found on the liver membranes obtained from immature growing dogs, but only the apo-E receptors were detected on th hepatic membranes of adult dogs. In this study, the expression of the apo-B,E receptors, as determined by canine LDL binding to the hepatic membranes, was found to be highly dependent on the age of the dog and decreased linearly with increasing age. Approximately 30 ng of LDL protein per milligram of membrane protein were bound via the apo-B,E receptors to the hepatic membranes of 7- to 8-wk-old immature dogs as compared with no detectable LDL binding in the hepatic membranes of adult dogs (greater than 1--1.5 yr of age). Results obtained by in vivo turnover studies of canine 125I-LDL correlated with the in vitro findings. In addition to a decrease in the expression of the hepatic apo-B,E receptors with age, these receptors were regulated, i.e., cholesterol feeding suppressed these receptors in immature dogs and prolonged fasting induced their expression in adult dogs. Previously, it was shown that the apo-B,E receptors were induced in adult livers following treatment with the hypocholesterolemic drug cholestyramine. In striking contrast, the apo-E receptors, as determined by apo-E HDLc binding, remained relatively constant for all ages of dogs studied (10--12 ng/mg). Moreover, the expression of the apo-E receptors was not strictly regulated by the metabolic perturbations that regulated the apo-B,E receptors. Similar results concerning the presence of apo-B,E and apo-E receptors were obtained in swine and in man. The hepatic membranes of adult swine bound only apo-E HDLc (apo-E receptors), whereas the membranes from fetal swine livers bound both LDL and apo-E HDLc (apo B,E and apo-E receptors). Furthermore, the membranes from adult human liver revealed the presence of the apo-E receptors as evidenced by the binding of 12--14 ng of HDLc protein per milligram of membrane protein and less than 1 ng of LDL protein per milligram. The membranes from the human liver also bound human chylomicron remnants and a subfraction of human HDL containing apo-E. These data suggest the importance of the E apoprotein and the apo-E receptors in mediating lipoprotein clearance, including chylomicron remnants, by the liver of adult dogs, swine, and man.

Apolipoprotein E Is Localized to the Cytoplasm of Human Cortical Neurons: A Light and Electron Microscopic Study

To clarify the localization of the glial protein apolipoprotein E (apoE) in human cortical neurons, we employed specific immunoelectron microscopy using a monoclonal antibody to human apoE in surgical specimens of temporal lobe. The specimens were rapidly fixed after excision from five patients undergoing surgery for medically intractable seizures, and postmortem material was also taken from one Alzheimers disease patient for comparison. Strong apoE immunoreactivity was observed in many astrocytes filling the perinuclear cytoplasm and distal processes completely. Some cortical neurons were also apoE-immunoreactive. ApoE immunoreactivity of neurons was less intense than glial cells and was distributed in a punctate fashion confined to the region of the cell body and proximal dendrites, but not distal processes. These findings suggest that apoE, which is presumably synthesized and stored by astrocytes, may be taken up by cortical neurons in younger adult humans. The presence of apoE in some human neurons may allow apoE to affect neuronal metabolism. Isoform-specific interactions with microtubule-associated proteins, such as tau or MAP2C, could influence the rate of pathology in neurodegenerative diseases such as Alzheimers disease.

Apolipoprotein E: diversity of cellular origins, structural and biophysical properties, and effects in Alzheimer's disease.

Apolipoprotein E4 (apoE4) is a major risk factor for Alzheimer’s disease (AD). Several hypotheses have been proposed to explain the association of the APOE ε4 allele with AD; however, the mechanisms underlying this association are largely unknown. Initially, apoE was thought to be synthesized primarily by astrocytes but not by neurons in the brain. However, subsequent studies have demonstrated that central nervous system neurons also express apoE under diverse physiological and pathological conditions. Detailed studies of the structure and biophysical properties of apoE isoforms have demonstrated unique properties distinguishing apoE4 from apoE3. Because the structural and biophysical properties of a protein determine how it functions under normal and abnormal conditions, apoE4, with its multiple cellular origins and multiple structural and biophysical properties, might contribute to the pathology of AD through several different mechanisms. Some of these mechanisms might be suitable targets for the development of new treatments for AD.

Introduction of human apolipoprotein E4 "domain interaction" into mouse apolipoprotein E.

Human apolipoprotein E4 (apoE4) binds preferentially to lower density lipoproteins, including very low density lipoproteins, and is associated with increased risk of atherosclerosis and neurodegenerative disorders, including Alzheimers disease. This binding preference is the result of the presence of Arg-112, which causes Arg-61 in the amino-terminal domain to interact with Glu-255 in the carboxyl-terminal domain. ApoE2 and apoE3, which have Cys-112, bind preferentially to high density lipoproteins (HDL) and do not display apoE4 domain interaction. Mouse apoE, like apoE4, contains the equivalent of Arg-112 and Glu-255, but lacks the critical Arg-61 equivalent (it contains Thr-61). Thus, mouse apoE does not display apoE4 domain interaction and, as a result, behaves like human apoE3, including preferential binding to HDL. To assess the potential role of apoE4 domain interaction in atherosclerosis and neurodegeneration, we sought to introduce apoE4 domain interaction into mouse apoE. Replacing Thr-61 in mouse apoE with arginine converted the binding preference from HDL to very low density lipoproteins in vitro, suggesting that apoE4 domain interaction could be introduced into mouse apoE in vivo. Using gene targeting in embryonic stem cells, we created mice expressing Arg-61 apoE. Heterozygous Arg-61/wild-type apoE mice displayed two phenotypes found in human apoE4/E3 heterozygotes: preferential binding to lower density lipoproteins and reduced abundance of Arg-61 apoE in the plasma, reflecting its more rapid catabolism. These findings demonstrate the successful introduction of apoE4 domain interaction into mouse apoE in vivo. The Arg-61 apoE mouse model will allow the effects of apoE4 domain interaction in lipoprotein metabolism, atherosclerosis, and neurodegeneration to be determined.

The role of apolipoprotein E in the nervous system.

Human apolipoprotein (apo)E, an important component of plasma lipoprotein metabolism, was recently linked to Alzheimers disease. Of the three common apoE alleles, epsilon 4 has emerged as a major risk factor. This review summarizes the data leading to this conclusion and discusses possible mechanisms for apoE involvement based on recent biochemical studies.