Development of the novel GlyT1 inhibitor, iclepertin (BI 425809), for the treatment of cognitive impairment associated with schizophrenia

Schizophrenia is a complex, heterogeneous psychiatric disorder associated with a wide range of debilitating symptoms that affect daily functioning and may also contribute to reduced life expectancy [1‐3]. In addition, individuals with schizophrenia may experience discrimination and social stigma as a result of their illness [4]. It is estimated that approximately 0.32% of the worldwide population, or approximately 24 million people globally, are affected by schizophrenia [4].

The onset of symptoms most frequently occurs in late adolescence or the twenties [4]. Symptoms of schizophrenia span three domains: positive, negative and cognitive (Fig. 1), and symptoms may vary in severity between individuals [1‐3]. Positive symptoms may include delusions and hallucinations as well as disorganised behaviour and speech, whereas negative symptoms are associated with social withdrawal, lack of motivation, decreased energy, loss of interest in normally enjoyable activities, a flattened affect and anhedonia (the inability to feel pleasure) [1‐3]. Cognitive symptoms, which are often present before the onset of psychosis and remain after successful treatment of psychosis with antipsychotics, include impairments in working memory and executive function, difficulty expressing thoughts, and reduced processing speed [1, 3]. Cognitive impairment associated with schizophrenia (CIAS) is common and contributes to functional disabilities in everyday life [1, 3, 5]. Thus, CIAS can strongly impair the patient’s quality of life [1, 3, 5] and may lead to poorer functional outcomes overall [6]. Indeed, the degree of CIAS is now thought to be the best predictor of long-term functional outcomes for patients with schizophrenia [7].

Antipsychotic drugs, the gold standard (and only approved pharmacological option) for the treatment of schizophrenia, primarily address the positive symptoms, such as delusions and auditory hallucinations, but do not effectively treat negative symptoms or CIAS, or fully address daily functioning [8]. Currently, there are no approved pharmacotherapies specifically targeting CIAS [5]. Although clozapine is effective at improving positive and negative symptoms in patients who did not previously respond to conventional treatments, and is widely recommended for treatment-resistant patients [9‐11], underutilisation of clozapine has been reported, resulting from treatment complexity, adverse effects and associated costs [12‐15]. Consequently, there is an urgent clinical need to develop effective pharmacotherapies to improve CIAS and thereby potentially improve the quality of life and daily functioning among patients with schizophrenia.

In the central nervous system, glutamatergic synapses are responsible for excitatory neuronal signalling in the cortex [16, 17]. When an action potential arrives at the presynaptic membrane, glutamate, the principal excitatory neurotransmitter in the brain, carries the signal across to the postsynaptic neuron [17, 18]. Glycine, another neurotransmitter released by both neurons and astrocytes, supports glutamatergic signalling [19]. Glycine has two major functions in the central nervous system: it acts as an inhibitory neurotransmitter in glycinergic neurons, primarily in the hindbrain [20] and also acts as a co-agonist for N-methyl-D-aspartate (NMDA) receptors in excitatory glutamatergic neurotransmission, primarily in the forebrain [19, 21]. The release and reuptake of glycine is controlled by the glycine transporter 1 (GlyT1), which is expressed in glial cells and presynaptically in neurons [19, 22].

Glutamate signals are detected postsynaptically, mainly by two types of ligand-gated ion channels at the postsynaptic neuron; these include α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors as well as NMDA receptors [16, 17, 23]. Upon an action potential, glutamate is released presynaptically [18] and first binds to the AMPA receptors and forms a channel for the influx of sodium ions into the postsynaptic neuron [17, 23] (Fig. 2). This causes the postsynaptic neuron to depolarise and triggers an action potential in the postsynaptic neuron, which travels down the axon and transmits an excitatory signal to other neurons [18]. Due to the depolarisation triggers, magnesium ions dissociate from NMDA receptors [17, 23, 24] and then, accompanied by binding of glutamate and glycine to the receptor, the NMDA receptor channel opens [24]. Afterwards, both calcium and sodium ions move into the postsynaptic neuron [17, 23]. This postsynaptic calcium signal further triggers intracellular signalling pathways that increase the likelihood of a postsynaptic response to subsequent signalling events [17, 23]. This increased response to subsequent events is known as synaptic plasticity and is believed to play a key role in learning and memory [24].

NMDA receptors also provide excitatory input to inhibitory gamma-aminobutyric acid (GABA)-ergic interneurons and reciprocal signalling between excitatory glutamatergic neurons. GABA-ergic interneuron excitation is crucial for cortical network function and excitatory/inhibitory (E/I) balance within the network. This supports the generation of coordinated neural oscillations and overall neural network synchronicity, which are vital for cognitive function and sensory processing [25, 26]. For example, gamma oscillations in the prefrontal cortex are especially important for processes relating to working memory and are thought to be influenced by NMDA receptors within this E/I balance network [3, 26, 27].

In patients with schizophrenia, prolonged hypofunction of NMDA receptors may lead to impaired synaptic plasticity and, thus, impaired cognitive functioning in patients [16]. Changes in NMDA receptor function in different regions of the brain may cause varying symptoms; while alterations in NMDA function in the prefrontal cortex may lead to changes in cognition, alteration in NMDA function in the hippocampus may be linked to the development of psychosis [25]. Beside the key role of the NMDA receptor function for synaptic plasticity, the mechanisms underlying the effects of NMDA receptor hypofunction in CIAS are hypothesised to be attributable to reduced excitatory input to NMDA receptors located on GABA-ergic inhibitory interneurons in cortical brain areas such as the prefrontal cortex. This leads to reduced functional inhibition of excitatory pyramidal neurons by interneurons, known as disinhibition of pyramidal cells, which causes an E/I imbalance and perturbed network function in the prefrontal cortex and therefore could explain cognitive dysfunction of patients with schizophrenia [26‐28].

Indeed, it is widely reported that patients with schizophrenia present with quantifiable sensory and neural network disturbances, which can be assessed using neurophysiological parameters measured using electroencephalography (EEG) [26, 27, 29‐32]. Furthermore, cortical network deficits, including disruptions of gamma oscillations, have been associated with cognitive processes, such as working memory and executive function [3]. For example, unlike healthy controls, patients with schizophrenia fail to increase gamma oscillatory power in the dorsolateral prefrontal cortex during working memory tasks [27].

The role of NMDA receptor hypofunction in disrupted network processing and CIAS is also supported by the effects of the non-competitive NMDA receptor antagonist ketamine [33]. When administered in healthy individuals, ketamine produces psychosis and symptoms similar to schizophrenia, including executive and cognitive impairment [33]. Furthermore, NMDA receptor antagonists have been reported to induce deficits in sensory processing and neural network connectivity in both animal models and healthy volunteers [34‐37].

Evidence from studies that modulate glutamate via other pathways also supports targeting of glutamatergic signalling to improve cognition; for example, inhibitors of D-serine and D-aspartate (D-amino acids that play key roles in the pathogenesis of schizophrenia) have been used to successfully address CIAS [38]. Specifically, sodium benzoate, a D-amino acid oxidase inhibitor, when administered at a dose of 2 g per day as an add-on to clozapine treatment, improved positive and negative symptoms as well as quality of life measures in patients with schizophrenia compared with those treated with placebo [39]. Another D-amino acid oxidase inhibitor, luvadaxistat, is currently being investigated as a potential treatment in the ongoing ERUDITE trial (NCT05182476) [40] following positive efficacy results in CIAS but not in treating negative symptoms in the INTERACT study (NCT03382639) [41]. Overall, given the evidence for the role of NMDA receptor hypofunction in CIAS, it can be hypothesised that increasing synaptic glycine levels by GlyT1 inhibition could normalise NMDA receptor hypofunction in patients with schizophrenia and thus facilitate glutamatergic signalling and synaptic plasticity. This would normalise NMDA receptor-mediated E/I imbalance in the cortex, which ultimately should lead to improvement of cognition in patients [22]. Therefore, inhibitors of GlyT1, which block the reuptake of glycine, could offer a promising treatment approach for CIAS [42, 43] (Fig. 2).

A number of GlyT1 inhibitors have been developed over the last 10 years to address CIAS. Sarcosine, reviewed elsewhere, was investigated in clinical trials assessing effects on symptom severity compared with placebo and demonstrated superior efficacy in reducing positive and negative symptom severity in specific subgroups of schizophrenia (chronic and non-treatment refractory disease), but its efficacy in relation to cognitive symptoms remains unclear [44‐46].

Bitopertin, a non-competitive GlyT1 inhibitor, has also been investigated as a potential treatment for schizophrenia symptoms. A Phase II trial in patients with dominant negative symptoms demonstrated modest improvements in negative symptoms following bitopertin treatment versus placebo as an add-on to standard of care therapy [47]. However, in subsequent Phase III confirmatory trials, treatment with bitopertin alone did not result in significant improvements in positive and negative symptoms as assessed using the positive and negative syndrome scale [48‐50].

The more recently emerging PF-03463275 is a competitive GlyT1 inhibitor currently undergoing Phase II trials [51]. When administered in a range of doses from 10 to 40 mg in patients with schizophrenia and healthy controls, PF-03463275 enhanced neuroplasticity in patients with schizophrenia and improved working memory accuracy when tested on healthy subjects. However, PF-03463275 administration did not abrogate ketamine-associated alteration in accuracy or reaction time [51]. Interestingly, analysis of the pooled effects of PF-03463275 on long-term potentiation across all doses in schizophrenia patients (10–60 mg) demonstrated a peak effect at the 40 mg dose (~ 75% GlyT1 occupancy), displaying an inverted ‘U’ dose–response profile [51], suggesting that dose selection and GlyT1 receptor occupancy are important for GlyT1 inhibitor efficacy. These positive effects on neuroplasticity support further investigation of GlyT1 inhibitors in the treatment of CIAS and emphasise the importance of optimal dose selection in clinical trials.

Following disappointing results in clinical trials with sarcosine and bitopertin, this review aims to summarise the most recent progress made in this field, and specifically the potential for the novel potent and selective GlyT1 inhibitor iclepertin to address cognitive symptoms in schizophrenia; to date, studies evaluating GlyT1 inhibitors have not targeted cognitive symptoms specifically.

Cognitive symptoms, including impairments in working memory and executive function, are common in schizophrenia and often lead to impaired daily functioning in patients [3, 5, 31]. However, to date, there are currently no approved pharmacological treatments for CIAS [4]. NMDA receptor hypofunction resulting in the imbalance in excitatory and inhibitory signalling has been implicated as a potential cause for symptoms associated with schizophrenia, particularly cognitive impairment. Increasing synaptic glycine levels to enhance glutamatergic signalling by blocking the reuptake of glycine via inhibitors of GlyT1 represents a promising target for the treatment of CIAS.

Iclepertin, a potent and selective GlyT1 inhibitor, has been demonstrated to be safe and well tolerated in healthy volunteers and in patients with schizophrenia [52‐55]. Non-clinically, iclepertin attenuated deficits in EEG parameters induced by the NMDA receptor antagonist MK-801 and demonstrated improved working and episodic memory performance in rodent cognition tasks at CSF concentrations in the range of approximately 1–6-fold of the IC₅₀ [56]. Central target engagement of iclepertin was demonstrated by a dose-dependent increase of glycine in rat and human CSF, reaching 50% glycine increase at CSF concentrations of about 1-fold IC₅₀ in rats and 2-fold IC₅₀ in humans at the 10 mg dose, respectively [57]. Phase I data demonstrated that plasma exposure of single ascending doses of iclepertin increased dose proportionally [53] at the predicted therapeutic exposure range of iclepertin, but less than dose proportionally at ≥ 50 mg [54].

The non-clinical findings on pro-cognitive efficacy were supported further by Phase II data in patients with CIAS, which demonstrated significant improvements in cognition versus placebo at 10 mg or 25 mg of iclepertin, with no additional benefit noted from the 25 mg dose compared with the 10 mg dose [52]. Three Phase III trials are currently ongoing to confirm these initial safety and efficacy findings and to report on the long-term effects of iclepertin on daily functioning in patients. If Phase III trials are successful, iclepertin may become the first approved once-daily pharmacotherapy to effectively improve cognition, with the potential to alleviate an urgent unmet clinical need for patients with schizophrenia who may be living with the daily burden of CIAS.