57 research outputs found
Fragment-based lead discovery on G-protein-coupled receptors
Introduction: G-protein-coupled receptors (GPCRs) form one of the largest groups of potential targets for novel medications. Low druggability of many GPCR targets and inefficient sampling of chemical space in high-throughput screening expertise however often hinder discovery of drug discovery leads for GPCRs. Fragment-based drug discovery is an alternative approach to the conventional strategy and has proven its efficiency on several enzyme targets. Based on developments in biophysical screening techniques, receptor stabilization and in vitro assays, virtual and experimental fragment screening and fragment-based lead discovery recently became applicable for GPCR targets. Areas covered: This article provides a review of the biophysical as well as biological detection techniques suitable to study GPCRs together with their applications to screen fragment libraries and identify fragment-size ligands of cell surface receptors. The article presents several recent examples including both virtual and experimental protocols for fragment hit discovery and early hit to lead progress. Expert opinion: With the recent progress in biophysical detection techniques, the advantages of fragment-based drug discovery could be exploited for GPCR targets. Structural information on GPCRs will be more abundantly available for early stages of drug discovery projects, providing information on the binding process and efficiently supporting the progression of fragment hit to lead. In silico approaches in combination with biological assays can be used to address structurally challenging GPCRs and confirm biological relevance of interaction early in the drug discovery project
Design Principles for Fragment Libraries: Maximizing the Value of Learnings from Pharma Fragment-Based Drug Discovery (FBDD) Programs for Use in Academia
Fragment-based drug discovery (FBDD) is well suited for discovering both drug leads and chemical probes of protein function; it can cover broad swaths of chemical space and allows the use of creative chemistry. FBDD is widely implemented for lead discovery in industry but is sometimes. used less systematically in academia. Design principles and implementation approaches for fragment libraries are continually evolving, and the lack of up-to-date guidance may prevent more effective application of FBDD in academia. This Perspective explores many of the theoretical, practical, and strategic considerations that occur within FBDD programs, including the optimal size, complexity, physicochemical profile, and shape profile of fragments in FBDD libraries, as well as compound storage, evaluation; and screening technologies. This:compilation of industry experience in FBDD will hopefully be useful for those pursuing FBDD in academia
Anthropogenic reaction parameters - the missing link between chemical intuition and the available chemical space
How do skilled synthetic chemists develop
such a good intuitive expertise
?
Why can we
only access such a small amount of the available chemical space
—
both in terms of the
re
actions used and the chemical scaffolds we make?
We argue here that these
seemingly
unrelated
questions
have a common root and
are strongly
interdependent
.
We performed a
comprehensive analysis of organic reaction parameters dating back to 1771 and discove
red
that
there are several
anthropogenic
factors
that limit the
reaction parameters and thus the
scop
e of synthetic
chemistry.
Nevertheless,
many of the anthropogenic limitations such as
the
narrow parameter space and the opportunity of the rapid and clear
feedback on the progress of
reactions appear to be crucial for the acquisition of valid and reliable chemical intuition.
In
parallel, however, all of these
same
factors represent limitations
for the
exploration of
available chemistry space and
we argue
th
at these
are thus at least partly responsible for
limited access to new chemistries. We advocate, therefore, that the present
anthropogenic
boundaries can be expanded by a more conscious expl
oration of “off
-
road” chemistry that
would also
extend the intuit
ive knowledge of trained chemists
The role of quantum chemistry in covalent inhibitor design
The recent ascent of targeted covalent inhibitors (TCI) in drug discovery brings new opportunities and challenges to quantum chemical reactivity calculations supporting discovery efforts. TCIs typically form a covalent bond with the targeted nucleophilic amino acid side chain. Their reactivity that can be both computed and experimentally
measured is therefore one of the key factors in determining inhibitory potency. Calculation of relevant quantum chemical descriptors and corresponding reaction barriers of model reactions represent efficient ways to predict intrinsic reactivities of covalent ligands. A more comprehensive description of covalent ligand binding is offered by mixed quantum mechanical/molecular mechanical (QM/MM) potentials.
Reaction mechanisms can be investigated by the exploration of the potential energy surface as a function of suitable reaction coordinates, and free energy surfaces can also be calculated with molecular dynamics based simulations. Here we review the methodological aspects and discuss applications with primary focus on high-end QM/MM simulations to illustrate the current status of quantum chemical support to covalent inhibitor design. Available QM approaches are suitable to identify likely reaction mechanisms and rate determining steps in the binding of covalent inhibitors. The efficient QM/MM prediction of ligand reactivities complemented with the computational
description of the recognition step makes these computations highly useful in covalent drug discovery
Favipiravir for the treatment of COVID-19 in elderly patients—what do we know after 2 years of COVID-19?
Since the appearance of coronavirus disease 2019 (COVID-19), numerous studies have been conducted to find effective therapeutics. Favipiravir (FVP) is one of the repurposed drugs which has been authorized in a few countries on an emergency basis to treat COVID-19. Elderly individuals especially 65 years or older are more prone to develop severe illness. We aim to provide a short summary of the current knowledge of the antiviral efficacy of favipiravir with respect to severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2)–infected elderly patients. We found that it is rather controversial whether favipiravir is effective against SARS-CoV-2 infection. Data regarding patients 65 years or older is not sufficient to support or reject the usage of favipiravir for COVD-19 treatment. Further studies would be advisable to elicit the efficiency of favipiravir in elderly COVID-19 patients
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