Achieving femtomolar affinities in structure-based drug design

Asta Zubrienė; Maija Kurtenoka; Vaida Paketurytė-Latvė; Janis Leitans; Elena Manakova; Mantas Žvirblis; Andris Kazaks; Vladislava Eimonta; Kaspars Tars; Saulius Gražulis; Vytautas Petrauskas; Jurgita Matulienė; Virginija Dudutienė; Kirill Shubin; Daumantas Matulis

doi:10.1007/s00249-025-01812-5

Achieving femtomolar affinities in structure-based drug design

Asta Zubrienė
, Maija Kurtenoka
, Vaida Paketurytė-Latvė
, Janis Leitans
, Elena Manakova
, Mantas Žvirblis
, Andris Kazaks
, Vladislava Eimonta
, Kaspars Tars
, Saulius Gražulis
, Vytautas Petrauskas
, Jurgita Matulienė
, Virginija Dudutienė
, Kirill Shubin^*
, Daumantas Matulis^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Developing small-molecule compounds as effective and safe pharmaceuticals relies on their ability to bind disease-associated proteins with high affinity and selectivity. However, achieving ultra-high affinity in the femtomolar range is a major challenge in medicinal chemistry due to the inherent constraints of protein-ligand interactions. Here, we introduce a novel class of di-meta-substituted fluorinated benzenesulfonamide compounds that achieve an extraordinary dissociation constant of 44 fM for carbonic anhydrase IX (CAIX). CAIX, a transmembrane enzyme implicated in hypoxic tumor progression through the increase of microenvironment acidity, represents a promising target for anticancer therapy. Inhibiting CAIX may help suppress tumor growth and improve cancer treatment outcomes. The newly developed compounds exhibit the highest affinity for CAIX reported to date and rank among the strongest known non-covalent small-molecule inhibitors.

Original language	English
Pages (from-to)	55-62
Journal	European Biophysics Journal
Volume	55
Issue number	1
DOIs	https://doi.org/10.1007/s00249-025-01812-5
Publication status	Published - Feb 2026
Externally published	Yes

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

Keywords

Binding affinity
Carbonic anhydrase IX
Drug discovery
Protein-ligand binding
Structural biology

Access to Document

10.1007/s00249-025-01812-5

Cite this

Zubrienė, A., Kurtenoka, M., Paketurytė-Latvė, V., Leitans, J., Manakova, E., Žvirblis, M., Kazaks, A., Eimonta, V., Tars, K., Gražulis, S., Petrauskas, V., Matulienė, J., Dudutienė, V., Shubin, K., & Matulis, D. (2026). Achieving femtomolar affinities in structure-based drug design. European Biophysics Journal, 55(1), 55-62. https://doi.org/10.1007/s00249-025-01812-5

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title = "Achieving femtomolar affinities in structure-based drug design",

abstract = "Developing small-molecule compounds as effective and safe pharmaceuticals relies on their ability to bind disease-associated proteins with high affinity and selectivity. However, achieving ultra-high affinity in the femtomolar range is a major challenge in medicinal chemistry due to the inherent constraints of protein-ligand interactions. Here, we introduce a novel class of di-meta-substituted fluorinated benzenesulfonamide compounds that achieve an extraordinary dissociation constant of 44 fM for carbonic anhydrase IX (CAIX). CAIX, a transmembrane enzyme implicated in hypoxic tumor progression through the increase of microenvironment acidity, represents a promising target for anticancer therapy. Inhibiting CAIX may help suppress tumor growth and improve cancer treatment outcomes. The newly developed compounds exhibit the highest affinity for CAIX reported to date and rank among the strongest known non-covalent small-molecule inhibitors.",

keywords = "Binding affinity, Carbonic anhydrase IX, Drug discovery, Protein-ligand binding, Structural biology",

author = "Asta Zubrienė and Maija Kurtenoka and Vaida Paketurytė-Latvė and Janis Leitans and Elena Manakova and Mantas {\v Z}virblis and Andris Kazaks and Vladislava Eimonta and Kaspars Tars and Saulius Gra{\v z}ulis and Vytautas Petrauskas and Jurgita Matulienė and Virginija Dudutienė and Kirill Shubin and Daumantas Matulis",

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year = "2026",

month = feb,

doi = "10.1007/s00249-025-01812-5",

language = "English",

volume = "55",

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Zubrienė, A, Kurtenoka, M, Paketurytė-Latvė, V, Leitans, J, Manakova, E, Žvirblis, M, Kazaks, A, Eimonta, V, Tars, K, Gražulis, S, Petrauskas, V, Matulienė, J, Dudutienė, V, Shubin, K & Matulis, D 2026, 'Achieving femtomolar affinities in structure-based drug design', European Biophysics Journal, vol. 55, no. 1, pp. 55-62. https://doi.org/10.1007/s00249-025-01812-5

TY - JOUR

T1 - Achieving femtomolar affinities in structure-based drug design

AU - Zubrienė, Asta

AU - Kurtenoka, Maija

AU - Paketurytė-Latvė, Vaida

AU - Leitans, Janis

AU - Manakova, Elena

AU - Žvirblis, Mantas

AU - Kazaks, Andris

AU - Eimonta, Vladislava

AU - Tars, Kaspars

AU - Gražulis, Saulius

AU - Petrauskas, Vytautas

AU - Matulienė, Jurgita

AU - Dudutienė, Virginija

AU - Shubin, Kirill

AU - Matulis, Daumantas

PY - 2026/2

Y1 - 2026/2

N2 - Developing small-molecule compounds as effective and safe pharmaceuticals relies on their ability to bind disease-associated proteins with high affinity and selectivity. However, achieving ultra-high affinity in the femtomolar range is a major challenge in medicinal chemistry due to the inherent constraints of protein-ligand interactions. Here, we introduce a novel class of di-meta-substituted fluorinated benzenesulfonamide compounds that achieve an extraordinary dissociation constant of 44 fM for carbonic anhydrase IX (CAIX). CAIX, a transmembrane enzyme implicated in hypoxic tumor progression through the increase of microenvironment acidity, represents a promising target for anticancer therapy. Inhibiting CAIX may help suppress tumor growth and improve cancer treatment outcomes. The newly developed compounds exhibit the highest affinity for CAIX reported to date and rank among the strongest known non-covalent small-molecule inhibitors.

AB - Developing small-molecule compounds as effective and safe pharmaceuticals relies on their ability to bind disease-associated proteins with high affinity and selectivity. However, achieving ultra-high affinity in the femtomolar range is a major challenge in medicinal chemistry due to the inherent constraints of protein-ligand interactions. Here, we introduce a novel class of di-meta-substituted fluorinated benzenesulfonamide compounds that achieve an extraordinary dissociation constant of 44 fM for carbonic anhydrase IX (CAIX). CAIX, a transmembrane enzyme implicated in hypoxic tumor progression through the increase of microenvironment acidity, represents a promising target for anticancer therapy. Inhibiting CAIX may help suppress tumor growth and improve cancer treatment outcomes. The newly developed compounds exhibit the highest affinity for CAIX reported to date and rank among the strongest known non-covalent small-molecule inhibitors.

KW - Binding affinity

KW - Carbonic anhydrase IX

KW - Drug discovery

KW - Protein-ligand binding

KW - Structural biology

UR - https://www.scopus.com/pages/publications/105027924857

U2 - 10.1007/s00249-025-01812-5

DO - 10.1007/s00249-025-01812-5

M3 - Article

C2 - 41553426

AN - SCOPUS:105027924857

SN - 0175-7571

VL - 55

SP - 55

EP - 62

JO - European Biophysics Journal

JF - European Biophysics Journal

IS - 1

ER -

Achieving femtomolar affinities in structure-based drug design

Abstract

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Keywords

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