Estrogen intake and copper depositions: implications for Alzheimer's disease?

We present a patient with chronic postmenopausal estrogen intake with presence of Kayser-Fleischer ring in the cornea and Alzheimer's disease and discuss the pathophysiological mechanisms of estrogen intake and copper accumulation in various tissues, including the central nervous system. Sonography was compatible with copper accumulation in the basal ganglia, but the patient showed no clinical signs of Wilson's disease. Magnetic resonance imaging and positron emission tomography revealed a typical pattern for Alzheimer's disease. We propose increased copper levels as a direct effect of estrogen intake due to an augmented ATP7A-mRNA in the intestine. Moreover, we discuss the impact of elevated free serum copper on accompanying Alzheimer's disease, knowing that copper plays a crucial role in the formation of amyloid plaques and tau aggregation. This might offer a partial explanation for the observation that postmenopausal estrogen therapy is associated with a higher risk of mild cognitive impairment and Alzheimer's disease.

Introduction

Copper deposition in the Descemet membrane of the cornea, known as Kayser-Fleischer ring, is a rare finding in daily practice. If present, it is usually assumed to be pathognomonic for Wilson's disease (WD; a hepatolenticular degeneration and autosomal recessive movement disorder), but a Kayser-Fleischer ring is also rarely seen in other diseases, mainly of hepatic or hematological origin, indicating an imbalance of copper homeostasis [1, 2]. Copper is virtually totally incorporated into ceruloplasmin while small amounts are bound to serum albumin. In WD, ceruloplasmin deficiency leads to copper depositions in the cornea and brain via a consecutive rise of free serum copper. Frequently, a Kayser-Fleischer ring can be detected prior to the appearance of neurological symptoms [3] and an efficient diagnosis and treatment of copper accumulation may prevent the development of the movement disorder.

Contraceptives with estrogenic effects are known to elevate serum copper and ceruloplasmin levels [4, 5]. The underlying pathomechanism is not fully understood, but several authors propose an increase of ceruloplasmin as a direct effect of estrogen and, consequently, a rise of total copper content in the serum [4, 5]. Whatever the mechanism, the alteration of copper homeostasis is not listed in the drug information of oral contraceptives. However, in the last years, 3 cases with corneal deposition due to chronic intake of contraceptives have been reported, showing that changes in serum copper can be of clinical importance [6, 7].

Case Report

A 68-year-old woman with a 4-year history of Alzheimer's disease (AD) was admitted to the University Eye Hospital in Freiburg, Germany, for surgery of a bilateral pterygium and cataract. Preinterventional slit-lamp examination revealed a yellow-greenish deposition in the posterior corneal stroma and the Descemet membrane at the limbus of both corneas (fig. 1a, b). Urine copper (58.5 µg/24 h), serum copper (106 µg/dl) and ceruloplasmin (38 mg/dl) levels as well as transaminases and bilirubin were within the normal ranges. Neurological examination showed a slight postural tremor of both upper limbs and the head. The tremor syndrome had been present since the patient's adolescence and, in the light of a positive family history, it was judged to be an essential tremor. Neither dystonic, atactic or bulbar symptoms nor extrapyramidal signs including rigidity were present. Thus, the diagnosis of WD could not be made. Due to progressive AD (‘probable AD’ according to NINCDS-ADRDA criteria), anomia and apraxia were present. The cognitive state of the patient was evaluated by Mini-Mental State Examination, where she reached 10 of 30 points, with 4 points for orientation (time, town, country, district), all 3 points for the registration of 3 words, 1 point for language (name a pencil) and 2 points for the 3-stage command; all speaking for a moderate to severe impairment. The patient reported a daily 2-mg postmenopausal hormone estradiol intake over the past 22 years until one year before.

Fig. 1

Ophthalmological findings: macroscopic view (a) and slit-lamp examination (b) revealed copper depositions within the Descemet membrane. c Coronary T1-weighted MRI showed temporoparietal-accentuated brain atrophy. d Sonography of the basal ganglia revealed hyperechogenicity of both lentiform nuclei, demonstrated here for the right lentiform nucleus (yellow) neighboring the right lateral ventricle (red).

Magnetic resonance imaging (MRI) revealed brain atrophy of the temporal and parietal lobes (fig. 1c). Susceptibility-weighted MRI showed no copper accumulation in the basal ganglia. Neurosonography of the midbrain and basal ganglia displayed a right accentuated hyperechogenicity of both lentiform nuclei (fig. 1d). In line with the clinical diagnosis, positron emission tomography (PET) studies revealed typical features of AD (fig. 2): [18F]fluorodeoxyglucose (18FDG) PET demonstrated a pronounced bilateral temporoparietal hypometabolism, while 11C-labeled Pittsburgh Compound-B ([11C]PIB) PET showed strong binding to cortical fibrillar amyloid-β depositions in an AD-typical distribution.

Fig. 2

Results of 18FDG (a) and [11C]PIB (b) PET examinations. a The upper- and lower-row images show transaxial 18FDG PET images and three-dimensional surface projections (left and right lateral views, top view, right and left mesial views) of regions with decreased 18FDG uptake (color-coded as Z score), respectively. Note the marked bilateral hypometabolism of the temporoparietal region and of the posterior cingulate gyrus/precuneus. A less marked hypometabolism was also found in the bilateral frontal and mesiotemporal lobe. b Depiction of the corresponding transaxial [11C]PIB PET images that show the typical regional pattern of fibrillar amyloid-β binding in AD (strongest in the frontal cortex and posterior cingulate gyrus/precuneus, less so in the temporoparietal cortex).

Discussion

The enzyme ATP7B facilitates the transfer of copper into the Golgi apparatus of hepatocytes, where copper is incorporated into ceruloplasmin. In WD, a mutation of the copper-transporting gene ATP7B leads to secondary ceruloplasmin deficiency with a reduced half-life. Free serum copper accumulates in tissues like the eye (Kayser-Fleischer ring, sunflower cataract), brain (mainly basal ganglia), kidney and liver. A Kayser-Fleischer ring can be detected in approximately 60% of presymptomatic patients with WD, whereas virtually every patient with WD and neurological symptoms presents corneal copper deposition [3, 8]. Furthermore, a Kayser-Fleischer ring has been reported in other hepatic and hematological diseases [1, 2]. In the latter cases, elevated serum copper level was detected, whereas ceruloplasmin remained normal. Therefore, a relative surplus of free serum copper seems to be the common factor for tissue accumulation, rather than the absolute amount of copper or ceruloplasmin.

An increase of ceruloplasmin and serum copper due to chronic estrogen administration has been known since 1966 [4, 5]. Moreover, both serum copper and ceruloplasmin are elevated during pregnancy [9], a physiologic state of raised estrogen levels. Several authors suggest an estrogen-induced increase of ceruloplasmin and, secondary to that, a rise of the amount of total copper [4, 5]. An explanation for a missing clinical manifestation of these increased serum copper levels might be that copper is incorporated into ceruloplasmin, preventing the accumulation of free serum copper. However, the occurrence of copper depositions in the cornea due to long-lasting estrogen intake argues for a direct impact of estrogens on copper uptake, since ceruloplasmin remains normal in these cases [6, 7].

Hardman et al. [10] found evidence that estrogen has a direct impact on the ATP7A transporter of human placental cells, leading to a stimulation of the copper transport via an increase of ATP7A-mRNA expression. Transferring these data to enterocytes, where ATP7A plays a crucial role for the regulation of copper uptake [11], estrogen could upregulate ATP7A-mRNA, inducing an increased copper uptake via the intestine. This seems plausible, since an adequate copper supply to the embryo under physiologic conditions must be on the basis of an elevated intestinal copper uptake of the expectant mother. Therefore, we propose that the increase of ceruloplasmin after estrogen treatment is secondary to an enhanced copper uptake. However, in patients with a Kayser-Fleischer ring under estrogen therapy, this hepatic compensatory mechanism seems to be disturbed, possibly due to having a defect on the ceruloplasmin gene or being heterocygotes for WD. New findings suggest an association of an ATP7B polymorphism and sporadic AD which might be of interest in this context, since this polymorphism results in a disturbed function of the copper transporter, leading to an increased level of free serum copper [12]. Since in our case estradiol therapy was discontinued one year ago, ceruloplasmin and serum copper were at normal levels. We did not restart estradiol therapy to prove the pathomechanism because of ethical considerations mentioned below. However, in the 3 cases previously described, the causality between estrogen intake and enhanced serum copper has been described [6, 7].

In WD, copper accumulation can be diagnosed by basal ganglia sonography, showing hyperechogenicity of the lentiform nucleus [13]. In our patient, neurosonography of the basal ganglia revealed a right accentuated hyperechogenicity of both lentiform nuclei, supporting copper deposition in the basal ganglia, without presenting neurological symptoms compatible with WD. Walter et al. [13] also found this hyperechogenicity in 2 of 3 presymptomatic patients with WD. This could be explained by the time lag ranging from 7 to 37 years between copper accumulation (with secondary neurodegeneration due to oxidative stress) and overt neurological symptoms [8]. Susceptibility-weighted MRI showed no incidence of copper accumulation in the brain, but abnormal MRI findings in presymptomatic WD seem to be rare [3].

The role of copper in the pathogenesis of AD is still controversial, but there is increasing evidence that besides iron and zinc, free serum copper is involved in the aggregation of amyloid-β-forming amyloid plaques [14]. Moreover, a meta-analysis confirmed increased serum copper levels in patients with AD [15]. Copper is a redox-active metal and plays an important role as a catalyst in the production of reactive oxygen species. Furthermore, copper is assumed to build complexes with tau protein [16], the second pathologic hallmark of AD. It seems noteworthy that the copper transporter ATP7A is present in the brain. A co-release of amyloid-β and copper into the synaptic cleft increases the probability of building a redox-active amyloid-β-copper complex leading to oxidative stress, which enhances the forming of amyloid plaques. Estrogen therapy could have an impact on the expression of the ATP7A transporter in the brain as well, but this has not been demonstrated yet.

Although a case report like ours does not necessarily provide evidence for causal relationships, it allows, nevertheless, formulating hypotheses for further investigations and research. Certainly, it cannot be proven that the occurrence of AD in the present case is due to estrogen therapy. However, it is very tempting to assume a causal role after more than 20 years of estradiol intake leading to a Kayser-Fleischer ring and presumed copper depositions in the basal ganglia and given the crucial role of copper in the pathogenesis of AD pathology. Furthermore, this hypothesis might offer a partial explanation for the observation that postmenopausal estrogen therapy is associated with a higher risk of mild cognitive impairment, which is commonly the first stage of AD [17].

In conclusion, we suggest that augmented ATP7A-mRNA in the intestine as a direct effect of estrogen therapy facilitates the absorption of copper, leading to increased serum copper levels. In some patients, hepatic function might be unable to cope with an increased copper load, resulting in corneal copper depositions and cerebral copper accumulation in the basal ganglia. Furthermore, similar to findings in WD patients, we demonstrate hyperechogenicity of both lentiform nuclei, indicating cerebral copper accumulation in the basal ganglia in our patient. Increased levels of free serum copper might have an impact on AD, since the same ATP7A transporter for copper homeostasis is present in the brain and copper plays a crucial role in oxidative stress, the formation of amyloid plaques and tau aggregation. Although we cannot provide evidence for causality in the present case, we want to stimulate further investigations on the impact of estrogen on copper homeostasis and the link between serum copper and the pathophysiology of AD, since this might have consequences for monitoring hepatic regulatory mechanisms in patients receiving estrogens.

Disclosure Statement

The authors have no relevant financial disclosures or conflict of interests to declare.