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Current paradigm of the 18-kDa translocator protein (TSPO) as a molecular target for PET imaging in neuroinflammation and neurodegenerative diseases

Insights into Imaging volume 3pages 111–119 (2012)Cite this article

Abstract

Neuroinflammation is a process characterised by drastic changes in microglial morphology and by marked upregulation of the 18-kDa translocator protein (TSPO) on the mitochondria. The continual increase in incidence of neuroinflammation and neurodegenerative diseases poses a major health issue in many countries, requiring more innovative diagnostic and monitoring tools. TSPO expression may constitute a biomarker for brain inflammation that could be monitored by using TSPO tracers as neuroimaging agents. From medical imaging perspectives, this review focuses on the current concepts related to the TSPO, and discusses briefly on the status of its PET imaging related to neuroinflammation and neurodegenerative diseases in humans.

Introduction

Medical imaging—from morphome to molecules

The spectrum of medical imaging extends from morphology, over function, to molecules. X-ray based imaging modalities [traditional X-ray and computed tomography (CT)] primarily deal with anatomy and patterns, whereas radionuclide imaging, including positron emission tomography (PET) and single photon emission computed tomography (SPECT), assess function and physiology [1] (Fig. 1). From the medical viewpoint, clinical molecular imaging can be broadly defined as the in vivo non-invasive visualisation, characterisation and measurement of disease processes at the molecular or cellular level using specific imaging probes [2]. It sets forth to detect the biochemical changes underlying diseases rather than to image the macroscopic structural results of pathological processes.

Fig. 1
figure 1

Medical imaging ranges from morphology to function, down to molecules. Clinical molecular imaging is broadly defined as the in vivo visualisation and measurement of disease processes at the cellular and molecular level. It is an emerging technology that allows the characterisation of interactions between molecular probes and biological targets

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The current trend of new medical imaging scanner design and development is based on multimodel and multiparametric approaches. Indeed PET and its hybrid imaging modalities PET/CT, and before long magnetic resonance imaging (MRI)/PET, are changing the way we practice medicine. To date, PET/CT is currently a diagnostic imaging technique used in many hospitals worldwide to provide services for patients, especially in the fields of oncology, neuroscience and cardiology [3]. In spite of the recent advances of molecular and imaging techniques, there is still a gap between basic biomedical research and its clinical applications. Nowadays clinical PET tracer still mainly refers to the commercially available 2-deoxy-2-[18F]fluoro-D-glucose ([18F]FDG). The impact of PET and its hybrid systems to medicine is limited by the worldwide shortage of radiochemistry facilities to produce novel PET tracers to detect various pathophysiological mechanisms or to specify diagnosis or even theranostics of neurodegenerative diseases.

With the launching of new hybrid imaging systems like MRI/PET, radiologists will expect to play an even more active role in directing development of the rapidly evolving field of medical imaging. Although not all practicing radiologists will engage in the field of research and sciences, it is worthwhile that they keep abreast of recent development of PET tracers in the areas as diverse as oncology, cardiology, metabolic diseases and neurology. In this tutorial article, we review the current concepts related to the pathophysiology of neuroinflammation and neurodegenerative diseases and give a glance on the status of PET imaging of 18-kDa translocator protein (TSPO) tracers in neuroinflammation of the living brain, with the aim of providing a basis for future discussions on the development of TSPO tracers for the diagnosis and therapy of neurodegenerative diseases.

PET is intrinsically quantitative for 3D neuroreceptor imaging

PET is an imaging technique in which molecular tracers labelled with positron emitters are injected into the human body to track biochemical and physiological processes [3]. Imaging agents used for PET are radioactive probes emitting positively charged anti-electrons (positrons). The positron travels a short distance (less than a millimetre) before it annihilates with any electron to give two photons of 511 keV travelling under a mutual angle of 180°. It is this pair of coincident high-energy photons that underlies the PET principle allowing in vivo quantitative three-dimensional (3D) imaging through coincident detection using a gantry of multiple detectors around the patient (Fig. 2). The genuine strength of this powerful molecular imaging modality is its picomolar sensitivity and the possibility of quantitative imaging of in vivo binding to the specific neuroreceptors like TSPO, dopamine receptors and serotonin receptors. PET allows a quantitative 3D reconstruction of the in vivo radioactivity levels of the isotope administrated to a patient [4] (Table 1). It can deliver quantitative measures of biochemical parameters such as the TSPO density in living brain. In vivo assessment of tracer binding to a receptor site is based on the principles of receptor pharmacology [5]. The success of in vivo receptor measurements is predetermined by the understanding of the underlying biological system and by applying the optimal pharmacological model. When done properly, neuroreceptor PET studies can provide useful contributions to clinical studies and also for drug discovery and development.

Fig. 2
figure 2

PET principle: imaging agents used for PET are radioactive probes emitting positively charged anti-electrons (positrons). The positron travels a short distance (1–3 mm) before it annihilates with any electron to give two photons of 511 keV travelling under a mutual angle of 180°. It is this pair of coincident high energy photons that underly the PET principle allowing in vivo quantitative 3D imaging through coincident detection using a gantry of multiple detectors around the patient

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Table 1 Comparison of radionuclide imaging and MRI as molecular imaging systems [28]
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Brain as an “immune privileged” organ: to be or not to be?

Neuroinflammation denotes central nervous system (CNS)-specific, inflammation-like glial responses that do not reproduce the classic characteristics of inflammation in the periphery but which may engender neurodegenerative events [6]. A neurodegenerative disease is defined as a progressive irreversible deterioration of the motor, sensory or cognitive functions associated with neuronal loss. Traditional concepts have tended to focus attention on pure neurodegenerative or inflammatory mechanisms, neglecting an integrated perspective. These two previously distinct areas of neuroscience are in fact highly related. Since 1873 the brain was classified as an “immune privileged” organ because it seemed to be not affecting by immune responses or inflammation. The organ does not reproduce the classic characteristics of inflammation as in other parts of body. However, there is a recent shift in the fundamental concept as more evidence has suggested the importance of immune-related inflammatory reactions in the brain [7]. It indicates a more active role of neuroinflammation in the pathophysiology of progressive neurodegenerative disorders. The responses and actions of microglial cells and astrocytes in the brain have an inflammation-like character. These cells play major roles in neuroinflammation and neurodegenerative diseases and they are involved in many complex cellular responses [8]. Many pathological events can trigger neuroinflammation and the primary insult can be infective, degenerative, metabolic or ischaemic. For example, acute inflammation is associated with trauma, stroke and encephalitis, whereas multiple sclerosis (MS), Alzheimer’s disease (AD), Parkinson’s disease (PD), Huntington’s disease (HD), and amyotrophic lateral sclerosis are some of those conditions involving chronic inflammation. Inflammation has been identified as an important factor in primary neurodegenerative disorders. In the past, the associated inflammatory glial responses in these diseases had often been regarded as non-specific “reactive gliosis” that deserved no further significance. This viewpoint might be related to insensitivity of the conventional anatomical imaging modalities, including MRI, to grey matter changes such as plaques, gliosis or subtle atrophy. However, several researchers have discovered that primary neurodegenerative disorders and neuroinflammation are intermingled by immune responses [7, 9] (Fig. 3). Collateral neuronal destruction and myelin damage can occur in the course of neuroinflammation and neurodegeneration [7]. For example, the decline of N-acetyl-aspartate (NAA) levels on MR spectroscopy has been shown to be an indicator for neuronal damage in neurodegenerative diseases such as MS [10]. In the light of these findings, both purely inflammatory and neurodegenerative pathologies are controlled and regulated by the common molecular mechanism with collateral neuronal damage [7]. Initially divergent events such as ischaemia, peroxysomal dysfunction or amyloid beta protein (Aβ) deposition clearly initiate involvement of the immune system, which in turn interacts with the nervous system and ultimately sets the pace of progressive tissue damage.

Fig. 3
figure 3

Collateral neuronal damage is clearly inherent to primary neuroinflammatory diseases, and neuroinflammation is a likely consequence of primary neurodegeneration. a In primary degenerative diseases like AD and in stroke, a non-immune-mediated CNS injury is initiated. Immune response cells, predominantly local microglia, marcophages and lymphocytes, are involved in the degenerative processes and elicit a secondary inflammatory reaction, which sets the pace of progressive neuronal damage. Some of these mechanisms might also occur at certain stages of MS. b In primary inflammatory CNS disease such as MS, activated immune cells—namely, microglia, macrophages and lymphocytes—attack a common target antigen of the brain, typically part of the myelin sheath. Demyelination, axonal transection and neuronal death can occur during the immune response. The loss of myelin might result in secondary axonal transection (outside-in damage) or, vice versa, death of an axon can lead to secondary demyelination (inside-out damage). Some of these sequences constitute the pathogenesis of diseases like AD

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Microglial activation fans the flame in neuroinflammation

Microglia are the critical convergence point for the many diverse triggers in orchestrating the activity of other immune cells in the brain [6]. These cells are derived from the monocytic lineage display high sensitivity to different types of CNS injury [11]. During neuroinflammation, microglia undergo drastic changes in their morphology, migrate towards the lesion site, proliferate, and produce neurotoxic factors such as proinflammatory cytokines and reactive oxygen species. Stroke, hypoxia, and trauma compromise neuronal survival and indirectly trigger neuroinflammation as microglia become activated in response to insult in an attempt to limit further injury. A mild autoimmune reaction with microglial activation can have neuroprotective function after CNS injury [9]. An acute insult may trigger oxidative and nitrosative stress, it is typically short lived and unlikely to be detrimental to long-term neuronal survival. On the contrary, chronic neuroinflammation is a longstanding and often self-perpetuating response that persists long after an initial injury or insult. It includes not only longstanding activation of microglia but also subsequent release of inflammatory factors. In chronic inflammation, immune response can be full-blown, including the activation of microglia, and damage the brain tissues by autoimmunogens [12]. That means activated microglia can be either friends or foes to neighbouring neurons. It is not yet clear how to manipulate them to minimise their damaging effects.

Overexpressed TSPO on the mitochondral membrane

TSPO, formerly known as peripheral benzodiapzepine receptor (PBR), is a ubiquitous high affinity cholesterol transporter found primarily in the outer mitochondrial membrane of steroid-synthesising cells. To a lesser extent, the protein is also found in the cell nucleus and plasma membrane. The new name was adopted in 2006 in view of new insights into its structure and molecular functions. Although TSPO is found in many tissue types, it is expressed at the highest levels under normal conditions in tissues that synthesise steroids [13]. It has high level of expression in organs such as adrenals, kidneys, lungs and spleen [14]. The TSPO is also found in many other regions of the body, including human iris, ciliary body, heart, liver, testis, blood cells and brain. The TSPO is expressed at low levels primarily on microglia in healthy brain. It is expressed by the mitochondria of activated microglial cells in response to a variety of pathogens and insults [12]. TSPO can also be expressed in macrophage in inflammatory tissues associated with tumours [15]. It is significantly upregulated in breast, prostate, colon and brain cancers with protein expression linked to cancer progression and poor survival rates [13]. TSPO is a part of the mitochondrial permeability transition pore (MPTP). The MPTP consists of at least three different subunits on the mitochondrial outer membrane, including the isoquinolone binding protein of 18 kDa (TSPO), a voltage-dependent anion channel of 32 kDa (VDAC) and an adenine nucleotide transporter of 30 kDa (ANT) [16] (Fig. 4). It contains inner and outer membrane contact sites to facilitate the passage of lipophilic molecules across the intermembrane space. The minimal functional unit or the binding site, however, is the 18-kDa protein, which mainly consists of five transmembrane domains. Its importance does not depend only on ligand binding but also on the subsequent effects of binding [8]. TSPO has four main functions: (1) cholesterol binding and transport into mitochondria, a key function in steroidogenesis and bile salt synthesis, (2) protein import for membrane biogenesis, and directly or indirectly for other cellular functions including apoptosis, cell proliferation, differentiation, and anion transport, (3) porphyrin binding and transport for heme synthesis, and (4) regulation of mitochondrial function and immune regulation [13, 16]. Although research suggests that there are multiple TSPO binding sites, the nature of these sites and their functional significance is still obscured [17]. It is not exactly known what the endogenous ligands of TSPO are but some propose they can be cholesterol, diazepam-binding inhibitor (DBI), a neuropeptide, or porphyrins [9]. It is possible that TSPO polymerisation is associated with steroidogensis and it results in a conformational change to the TSPO binding sites [17].

Fig. 4
figure 4

TSPO structures and functions. It is a hetero-oligomeric complex and consists of at least three different subunits, including the isoquinolone binding protein of 18-kDa TSPO, a voltage-dependent anion channel (VDAC) and an adenine nucleotide transporter (ANT). It contains inner and outer membrane contact sites to facilitate the passage of lipophilic molecules across the intermembrane space. The minimal functional unit or the binding site, however, is the 18-kDa protein. TSPO has four main functions: (1) cholesterol binding and transport into mitochondria, a key function in steroidogenesis and bile salt synthesis, (2) protein import for membrane biogenesis, and other cellular functions including apoptosis, cell proliferation, and differentiation, (3) porphyrin binding and transport for heme synthesis, and (4) regulation of mitochondrial functions

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In the CNS, TSPO ligands have been found to stimulate synthesis of neurosteroids involved in diverse functions, from regulation of apoptosis to reduction of anxiety via modulation of GABAA receptor [16]. The TSPO expression is low in normal brain but it is upregulated in the brain at sites of injury and inflammatory tissues associated with tumour. The molecular mechanisms underlying these conditions are unknown, although some factors, such as reactive oxygen species, interleukin 1 and tumour necrosis factor (TNF)α, may play a role. Local TSPO overexpression in response to damage makes it a potentially ideal and sensitive marker for the detection of subtle changes in the region of brain insult (Fig. 5).

Fig. 5
figure 5

In vivo TSPO imaging by PET. PET imaging of microglial cells in vivo involves utilising ligands labelled with 11C or 18F radioisotopes that bind translocator protein (TSPO) expressed on the outer mitochondrial membrane in microglia. The radioisotope undergoes positron emission decay underlying the principle of PET imaging

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[11C]PK11195: the workhorse for TSPO imaging and its limitations

PK11195 [1-(2-chlorophenyl)-N-methyl-N-(1-methylpropyl)-3-isoquinoline carboxamide] is the first non-benzodiazepine and selective TSPO ligand labelled with carbon-11. It was discovered in 1984 and named by a French company, Pharmuka [18]. It remains most widely used in TSPO PET imaging with nanomolar binding affinity and it is the prototypical reference [19]. [11C]PK11195 has been used in many human CNS studies, including Rasmussen’s encephalitis, MS, AD, PD, amyotrophic lateral sclerosis, HD, HIV, herpes encephalitis, and neuropsychiatric disorders such as schizophrenia [16]. Studies found increased binding of [11C]PK11195 in corresponding MR regions of focal gadolinium-enhanced lesions and normal-appearing white matter (NAWM) in MS patients [20]. Brain atrophy, correlating with disease duration and disability of MS is directly related to [11C]PK11195 uptake, NAWM and inflammatory-related T2 hyperintense lesions [20, 21]. A study also showed an increase in brain uptake of [11C]PK11195 in MS patients during acute relapse [21]. Taken together, these studies suggest that microglial activation is of central importance in the pathophysiology of MS and can be visualised with PET using TSPO tracers.

In cerebral infarction, [11C]PK11195 is a useful tool to investigate acute neuroinflammatory changes related to cerebral infarct and could be beneficial in the evaluation of neuroprotective regimens related to microglial deregulation [22]. Aβ is known as a pathological substance in AD and is assumed to coexist with a degree of activated microglia in the brain. A few studies showed in vivo microglial activation in the brain of patients with mild to moderate AD using PET with [11C]PK11195, but the role is limited in severe AD [12, 23]. Increased microglial activation has been observed in patients with HD and presymptomatic carriers by [11C]PK11195 PET imaging [24]. In HD, the degree of microglial activation in the striatum has been found to correlate with D2 receptor dysfunction using PET with [11C]raclopride [25]. More recent studies suggest neuroinflammation might have a crucial role in neuropsychiatric disorders such as schizophrenia [26, 27]. Although there was large individual variation in humans, binding of [11C]PK11195 was increased in brain areas corresponding to different pathological processes in ongoing or recent clinical deficits. TSPO imaging with PET might provide insight into the process beyond the realm of traditional neuroimaging techniques.

Although it is well established that [11C]PK11195 shows increased uptake in a wide array of neurodegenerative disorders, it suffers from unresolved methodological and kinetic issues. There is low sensitivity and a limited capacity to quantify subtle TSPO expression in vivo. Relatively low receptor affinity could lead to low binding potential, which results from substantial binding of the tracer to other parts of the body. It suffers from high plasma protein binding and high non-specific binding likely related to high lipophilicity. The more lipophilic molecule is undesirable not only for slowing passive brain entry but also for increasing high non-specific binding to brain fats and protein. Relatively poor penetration of the blood brain barrier (BBB) and low brain uptake also lead to poor signal-to-noise ratio on PET imaging. Also, the lack of sensitivity and specificity and highly variable kinetic behaviour of [11C]PK11195 have precluded the development of a standard quantitative method of analysis [8, 14]. Without an on-site cyclotron facility, the short half-life of carbon-11 (t1/2 = 20.38 min) also limits PET imaging using [11C]PK11195 in routine clinical practice.

Current trend of novel potential tracers

In the light of the limitations of [11C]PK11195, many groups worldwide are actively engaged in a search for new radiotracers with improved capacities to image and quantify TSPO expression. In the literature, a number of excellent comprehensive reviews have been published on TSPO imaging [8, 9, 14, 16, 28]. Schweitzer et al. [16] and Rupprecht et al. [9] offer more details on the updated trend of TSPO radiotracers development.

TSPO radiotracers can be basically subdivided into seven chemical classes. Extensive research during recent years has led to the development of more than 50 new TSPO tracers [8, 14, 16, 29]. New tracers that used in human studies include [11C]DAA1106, [18F]FEDAA1106, [11C]PBR28, [11C]vinpocetine, [11C]AC-5216, [11C]DPA713 and [18F]DPA714 [3038] (Table 2). The studies in humans are at their initial stages with sporadic findings. From the glimpse of information, [11C]DAA1106, [18F]FEDAA1106, and [11C]PBR28 have shown significantly increased binding in living brain. The binding potential of [11C]vinpocetine is higher than [11C]PK11195 in MS patients. [18F]DPA-714, a close analogue of DPA-713, is also a promising PET tracer and has recently demonstrated high affinity for the TSPO with better uptake and binding potential than [11C]PK11195 [19, 38]. More recent studies show [11C]SSR180575, the first TSPO radioligand based on an indoleacetamide scaffold, has a better capacity than [11C]PK11195 to distinguish inflammatory tissue from healthy brain tissue [39, 40]. Discrepancies are found between the results of the binding affinities of different new TSPO radiotracers, and they showed heterogeneity in binding potentials in humans [9, 16, 41, 42].

Table 2 Examples of new potential PET tracers for TSPO imaging in clinical studies
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Most of the new TSPO tracers are, however, still in the infancy of investigation and some show mixed-affinity binding in human [41, 42]. Many research efforts in preclinical studies are aimed at the following key areas: (1) ligand metabolic stability, (2) specific binding potential (BP), (3) ligand-receptor kinetics, and (4) quantitative methods. The new TSPO tracer must show high affinity and selectivity for the receptor. Ideally, a PET radiotracer should enter the brain and interact selectively with its target in the absence of troublesome radiometabolites. Practically, potential problems related to radiometabolites of the tracer must be limited through effective radiotracer design. It is essential for accurate in vivo measurement of the density of a target protein like TSPO. Binding potential measures, obtained with PET and a specific radiotracer, are considered to be proportional to the receptor density in vivo and high BP is crucial for TSPO quantification [5]. Suitable brain pharmacokinetics in relation to radiolabel half-life with observable brain uptake and washout kinetics is also desirable for measuring ligand-receptor interaction (Fig. 6).

Fig. 6
figure 6

Schematic representation of TSPO radiotracer in the brain shows the fates of TSPO radiotracer and its radiometabolites passing through the brain-blood barrier (BBB). Radiotracer design for TSPO for the brain aims to achieve optimal passive diffusion across the BBB without impediment by efflux transporters (E.T.) to give a high specific binding (indicated by red circles). Many research efforts are aimed at (1) radiotracer metabolic stability (no/less radiometabolites), (2) high binding potential (high specific binding), (3) ligand-receptor kinetics (to optimise kinetic modelling), and (4) quantitative methods (T radiotracer, M radiometabolite, f free, b bound, nb non-specific binding, sb specific binding)

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Perspectives

There is accumulating evidence that neuroinflammation plays a crucial role in the development and progression of many neurodegenerative disorders such as MS, AD and HD. Collateral neuronal damage is clearly inherent to primary neuroinflammation, and neuroinflammation is a likely sequel of primary neurodegenerative diseases. It is important to understand the mechanisms that initiate neuroinflammation and neurodegeneration. Many questions remain regarding the use of TSPO tracers as diagnostic tools to assess activation of microglia. Overexpressed TSPO constitutes an important target for the detection or novel treatment of neuroinflammation and neurodegenerative disorders. The concept of multiple TSPO binding sites, variable conformational states of the protein and mixed binding affinity in living brain needs to be addressed when developing new PET TSPO radiotracers. Provided the broad spectrum of putative applications of TSPO ligands, further studies are eagerly awaited. With further development of potential tracers by better understanding of the protean nature of the receptor in healthy and diseased brain, PET imaging of the TSPO could offer a non-invasive modality for early diagnosis and theranostics of CNS diseases in ways beyond the scope of conventional imaging techniques.

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Acknowledgments

This work was supported by the FP6 European Networks of Excellence EMIL (LSHC-CT-2004-503569) and DIMI (LSHB-CT2005-5121146), and the STREP RATstream, (LSHM-CT-2007-037846).

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  1. CEA, I2BM, Service Hospitalier Frédéric Joliot, 4 place du Général Leclerc, 91401, Orsay, France

    Alex Sik Chung Ching, Bertrand Kuhnast, Annelaure Damont, Dirk Roeda, Bertrand Tavitian & Frédéric Dollé

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  1. Alex Sik Chung Ching
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  2. Bertrand Kuhnast
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Correspondence to Alex Sik Chung Ching.

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Ching, A.S.C., Kuhnast, B., Damont, A. et al. Current paradigm of the 18-kDa translocator protein (TSPO) as a molecular target for PET imaging in neuroinflammation and neurodegenerative diseases. Insights Imaging 3, 111–119 (2012). https://doi.org/10.1007/s13244-011-0128-x

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  • DOI: https://doi.org/10.1007/s13244-011-0128-x

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