Mutually Rewarding Academia-Industry Collaborations in the Field of Chemical Biology.

Breakthroughs in life sciences require multidisciplinary research. Activities in academia and industry are often complementary, so collaborations between both parties hold great potential for achieving superior overall results and accelerating innovation in life sciences. This special collection highlights successful examples of academia industry collaborations in the field of chemical biology and should encourage future teamwork for the benefit of society.

EFMC: Trends in Medicinal Chemistry and Chemical Biology.

Ground-breaking research in disease biology and continuous efforts in method development have uncovered a range of potential new drug targets. Increasingly, the drug discovery process is informed by technologies involving chemical probes as tools. Applications for chemical probes comprise target identification and assessment, as well as the qualification of small molecules as chemical starting points and drug candidates. Progress in probe chemistry has opened the way to novel assay formats and pharmaceutical compound classes. The European Federation of Medicinal Chemistry and Chemical Biology (EFMC) has launched the Chemical Biology Initiative to advance science in the field of medicinal chemistry and chemical biology, while representing all members of this extended scientific community. This review provides an overview of the many important developments in the field of chemical biology that have happened at the lively interface of academic and industrial research.

A practical approach to the optimization of positron emission tomography imaging agents for the central nervous system.

The discovery of novel imaging agents for positron emission tomography (PET) relies on medicinal chemistry best practices, including a good understanding of molecular and pharmacological properties required for the acquisition of relevant, high-quality images. This short note reviews the characteristics of a series of clinically successful imaging agents, providing guidance for the optimization of such molecular tools. PET imaging plays an important role in staging disease and in helping clinical dose selection, which is critical for the efficient development of drug candidates.

Regional brain mGlu5 receptor occupancy following single oral doses of mavoglurant as measured by [11C]-ABP688 PET imaging in healthy volunteers.

Mavoglurant binds to same allosteric site on metabotropic glutamate receptor 5 (mGluR5) as [11C]-ABP688, a radioligand. This open-label, single-center pilot study estimates extent of occupancy of mGluR5 receptors following single oral doses of mavoglurant, using [11C]-ABP688 positron emission tomography (PET) imaging, in six healthy males aged 20-40 years. This study comprised three periods and six subjects were divided into two cohorts. On Day 1 (Period 1), baseline clinical data and safety samples were obtained along with PET scan. During Period 2 (1-7 days after Period 1), cohort 1 and 2 received mavoglurant 25 mg and 100 mg, respectively. During Period 3 (7 days after Period 2), cohort 1 and 2 received mavoglurant 200 mg and 400 mg, respectively. Mavoglurant showed the highest distribution volumes in the cingulate region with lower uptake in cerebellum and white matter, possibly because myelinated axonal sheets maybe devoid of mGlu5 receptors. Maximum concentrations of mavoglurant were observed around 2-3.25 h post-dose. Mavoglurant passed the blood-brain barrier and induced dose- and exposure-dependent displacement of [11C]-ABP688 from the mGluR5 receptors, 3-4 h post-administration (27%, 59%, 74%, 85% receptor occupancy for mavoglurant 25 mg, 100 mg, 200 mg, 400 mg dose, respectively). There were no severe adverse effects or clinically significant changes in safety parameters. This is the first human receptor occupancy study completed with Mavoglurant. It served to guide the dosing of mavoglurant in the past and currently ongoing clinical studies. Furthermore, it confirms the utility of [11C]-ABP688 as a unique tool to study drug-induced occupancy of mGlu5 receptors in the living human brain.

The Chemical Biology-Medicinal Chemistry Continuum: EFMC's Vision.

The European Federation for Medicinal chemistry and Chemical biology (EFMC) is a federation of learned societies. It groups organizations of European scientists working in a dynamic field spanning chemical biology and medicinal chemistry. New ideas, tools, and technologies emerging from a wide array of scientific disciplines continuously energize this rapidly evolving area. Medicinal chemistry is the design, synthesis, and optimization of biologically active molecules aimed at discovering new drug candidates - a mission that in many ways overlaps with the scope of chemical biology. Chemical biology is by now a mature field of science for which a more precise definition of what it encompasses, in the frame of EFMC, is timely. This article discusses chemical biology as currently understood by EFMC, including all activities dealing with the design and synthesis of biologically active chemical tools and their use to probe, characterize, or influence biological systems.

Positron Emission Tomography Imaging of Autotaxin in Thyroid and Breast Cancer Models Using [18F]PRIMATX.

Autotaxin (ATX) is a secreted enzyme responsible for producing lysophosphatidic acid (LPA). The ATX/LPA signaling axis is typically activated in wound healing and tissue repair processes. The ATX/LPA axis is highjacked and upregulated in the progression and persistence of several chronic inflammatory diseases, including cancer. As ATX inhibitors are now progressing to clinical testing, innovative diagnostic tools such as positron emission tomography (PET) are needed to measure ATX expression in vivo accurately. The radiotracer, [18F]PRIMATX, was recently developed and tested for PET imaging of ATX in vivo in a murine melanoma model. The goal of the present work was to further validate [18F]PRIMATX as a PET imaging agent by analyzing its in vivo metabolic stability and suitability for PET imaging of ATX in models of human 8305C thyroid tumor and murine 4T1 breast cancer. [18F]PRIMATX displayed favorable metabolic stability in vivo (65% of intact radiotracer after 60 min p.i.) and provided sufficient tumor uptake profiles in both tumor models. Radiotracer uptake could be blocked by 8-12% in 8305C thyroid tumors in the presence of ATX inhibitor AE-32-NZ70 as determined by PET and ex vivo biodistribution analyses. [18F]PRIMATX also showed high brain uptake, which was reduced by 50% through the administration of ATX inhibitor AE-32-NZ70. [18F]PRIMATX is a suitable radiotracer for PET imaging of ATX in the brain and peripheral tumor tissues.

Perspectives and Opportunities in Medicinal Chemistry: A View from the Novartis Institute for BioMedical Research in Basel, Switzerland.

An opinion on changes and opportunities for the pharmaceutical industry in Switzerland, as seen from the Global Discovery Chemistry platform of the Novartis Institutes for BioMedical Research in Basel.

Fostering Research Synergies between Chemists in Swiss Academia and at Novartis.

We present a short overview of the way Novartis chemists interact and collaborate with the academic chemistry community in Switzerland. This article exemplifies a number of collaborations, and illustrates opportunities to foster research synergies between academic and industrial researchers. It also describes established programs available to academic groups, providing them access to Novartis resources and expertise.

Medicinal Chemistry and Chemical Biology Highlights.

The Division of Medicinal Chemistry and Chemical Biology of the Swiss Chemical Society is an active member of the European Federation for Medicinal Chemistry (EFMC), whose mission is to advance the science of medicinal chemistry in Europe. EFMC promotes scientific exchange, rewards scientific excellence, facilitates communication and networking, and provides training and mentoring. We give here an overview of its current initiatives and scientific activities.

Medicinal Chemists Don't Just Make Drugs - The Art of Developing Low Molecular Weight Imaging Agents in Switzerland.

Radiolabeled molecular imaging agents are useful to study drug distribution, target engagement and disease progression in human patients. Medicinal chemists often develop them in parallel to drug discovery programs, to facilitate clinical development or to better understand physiological and pathological processes. While the properties required for imaging agents differ from those of drug candidates, their optimization follows similar principles. Developing them for clinical use also requires a multidisciplinary approach, and is best conducted in a close partnership between pharmaceutical and academic research centers. This article reviews recent scientific advances towards the identification and development of low molecular weight imaging agents in Switzerland.

Developing Low Molecular Weight PET and SPECT Imaging Agents.

Imaging agents for positron emission tomography (PET) and single-photon emission computerized tomography (SPECT) have shown their utility in many situations, answering clinical questions related to drug development and medical considerations. The discovery and development of imaging agents follow a well-understood process, with variations related to available starting points and to the envisaged imaging application. This article describes the general development path leading from the expression of an imaging need and project initiation to a clinically usable imaging agent. The definition of the project rationale, the design and optimization of early leads, and the assessment of the imaging potential of an imaging agent candidate are followed by preclinical and clinical development activities that differ from those required for therapeutic agents. These include radiolabeling with a positron emitter and first-in-human clinical studies, to rapidly evaluate the ability of a new imaging agent to address the questions it was designed to answer.

An Active Member of the EFMC: The Division of Medicinal Chemistry and Chemical Biology of the Swiss Chemical Society.

The Division of Medicinal Chemistry and Chemical Biology (DMCCB) of the Swiss Chemical Society is an active contributor to the dynamics of the Swiss and European scientific communities. Founded in 1987, it pursues its mission to foster relationships among its academic and industrial members, to facilitate exchange by organizing symposia and courses, and to encourage scientific excellence. This article presents the DMCCB and highlights both its offer to the community and its participation in the activities of EFMC, the European Federation for Medicinal chemistry and Chemical biology.

The Facets of Diversity: The EFMC Perspective.

Diversity in science refers to cultivating talent, while promoting full inclusion across the community. In medicinal chemistry and chemical biology, it enhances creativity and encourages contributions from multiple perspectives, leading to better decision making and broader scientific impact. The European Federation for Medicinal chemistry and Chemical biology (EFMC) embraces and promotes diversity, to ensure representation of all talents, and enable equality of opportunity through fairness and transparency. EFMC has historically paid continuous attention to diversity in terms of culture, geography and equilibrium between academia and industry, with over the last few years a focus on increasing gender balance, aiming at a fair representation of the scientific community and equal opportunities independently of gender. EFMC promotes cultural diversity as it reinforces openness and mutual respect. All scientific organizations of a scope compatible with its remit are welcome within EFMC, where their members benefit from a welcoming, psychologically safe, and stimulating environment. Herein, we describe the state of diversity within the EFMC, how the situation has evolved over the years and where diversity should be further encouraged.

Quinazolinedione sulfonamides: a novel class of competitive AMPA receptor antagonists with oral activity.

Quinazoline-2,4-diones with a sulfonamide group attached to the N(3) ring atom constitute a novel class of competitive AMPA receptor antagonists. One of the synthesized compounds, 28, shows nanomolar receptor affinity, whereas other examples of the series display oral anticonvulsant activity in animal models.

Double dissociation of spike timing-dependent potentiation and depression by subunit-preferring NMDA receptor antagonists in mouse barrel cortex.

Spike timing-dependent plasticity (STDP) is a strong candidate for an N-methyl-D-aspartate (NMDA) receptor-dependent form of synaptic plasticity that could underlie the development of receptive field properties in sensory neocortices. Whilst induction of timing-dependent long-term potentiation (t-LTP) requires postsynaptic NMDA receptors, timing-dependent long-term depression (t-LTD) requires the activation of presynaptic NMDA receptors at layer 4-to-layer 2/3 synapses in barrel cortex. Here we investigated the developmental profile of t-LTD at layer 4-to-layer 2/3 synapses of mouse barrel cortex and studied their NMDA receptor subunit dependence. Timing-dependent LTD emerged in the first postnatal week, was present during the second week and disappeared in the adult, whereas t-LTP persisted in adulthood. An antagonist at GluN2C/D subunit-containing NMDA receptors blocked t-LTD but not t-LTP. Conversely, a GluN2A subunit-preferring antagonist blocked t-LTP but not t-LTD. The GluN2C/D subunit requirement for t-LTD appears to be synapse specific, as GluN2C/D antagonists did not block t-LTD at horizontal cross-columnar layer 2/3-to-layer 2/3 synapses, which was blocked by a GluN2B antagonist instead. These data demonstrate an NMDA receptor subunit-dependent double dissociation of t-LTD and t-LTP mechanisms at layer 4-to-layer 2/3 synapses, and suggest that t-LTD is mediated by distinct molecular mechanisms at different synapses on the same postsynaptic neuron.

EFMC, Medicinal Chemistry and Chemical Biology in Europe.

This article is a reflection on the development of medicinal chemistry and chemical biology in Europe, and how the European Federation for Medicinal Chemistry (EFMC) helps the scientific community address its changing scope in a proactive manner. Networking, knowledge exchange and representation, as well as the acceptance and integration of novel scientific developments, are keys to a healthy and dynamic scientific community. This article also reviews some of the forces that shape the medicinal chemistry and chemical biology continuum, including cross-fertilization, digitalization, and the outsourcing of synthetic and characterization work to focus on productivity and scientific excellence.

The Young Scientists Network: How the European Federation for Medicinal Chemistry (EFMC) Became Young Again.

The European Federation for Medicinal Chemistry (EFMC) created the Young Scientists Network (YSN) to support early-career medicinal chemists and chemical biologists. By doing this, it addressed the rapid changes taking place in the scientific community and in our society, such as the rise of social media, the evolution of the gender balance in the scientific population, and educational needs. Creating the YSN was also a way to ensure that the next generation of scientists would contribute to shaping EFMC's strategy, while recognizing and addressing their needs. The YSN was set up as a very dynamic concept, and has now developed to the point where its impact is evident. The activities it promotes complement EFMC's community support and scientific opportunities, rejuvenating the Federation and preparing it for the future. It also provides opportunities for many brilliant young scientists, who do not hesitate to invest time and energy in supporting our community and shaping their own future.

Evaluation of 5H-Thiazolo[3,2-α]pyrimidin-5-ones as Potential GluN2A PET Tracers.

We describe here our efforts to develop a PET tracer for imaging GluN2A-containing NMDA receptors, based on a 5H-thiazolo[3,2-α]pyrimidin-5-one scaffold. The metabolic stability and overall properties could be optimized satisfactorily, although binding affinities remained a limiting factor for in vivo imaging. We nevertheless identified 7-(((2-fluoroethyl)(3-fluorophenyl)amino)-methyl)-3-(2-(hydroxymethyl)cyclopropyl)-2-methyl-5H-thiazolo-[3,2-α]pyrimidin-5-one ([18 F]7b) as a radioligand providing good-quality images in autoradiographic studies, as well as a tritiated derivative, 2-(7-(((2-fluoroethyl)(4-fluorophenyl)amino)methyl)-2-methyl-5-oxo-5H-thiazolo[3,2-α]pyrimidin-3-yl)cyclopropane-1-carbonitrile ([3 H2 ]15b), which was used for the successful development of a radioligand binding assay. These are valuable new tools for the study of GluN2A-containing NMDA receptors, and for the optimization of allosteric modulators binding to the pharmacophore located at the dimer interface of the GluN1-GluN2A ligand-binding domain.