In silico discovery of thioglycoside analogues as donor-site inhibitors of glycosyltransferase LgtC

Olimpo Sierra-Hernández; Oscar Saurith-Coronell; Jackson J. Alcázar; Eliceo Cortés; Maryury C. Flores-Sumoza; Juan D. Rodríguez-Macías; José R. Mora; Yovani Marrero-Ponce; Ernesto Contreras-Torres; Edgar A. Márquez Brazón

doi:10.1038/s41598-026-43638-x

In silico discovery of thioglycoside analogues as donor-site inhibitors of glycosyltransferase LgtC

Olimpo Sierra-Hernández^*
, Oscar Saurith-Coronell
, Jackson J. Alcázar
, Eliceo Cortés
, Maryury C. Flores-Sumoza
, Juan D. Rodríguez-Macías
, José R. Mora
, Yovani Marrero-Ponce
, Ernesto Contreras-Torres
, Edgar A. Márquez Brazón^*

^*Corresponding author for this work

Universidad del Norte
Universidad del Desarrollo
Institución Universitaria de Barranquilla
Universidad Simón Bolívar
Universidad Libre
Universidad Panamericana (UP)
Universidad San Francisco de Quito

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

Abstract

The growing prevalence of multidrug-resistant Gram-negative pathogens highlights the urgent need for therapeutic strategies that complement traditional antibiotics by targeting essential virulence pathways. Glycosyltransferase LgtC, a key enzyme in lipooligosaccharide (LOS) biosynthesis, represents an attractive target for antivirulence approaches because of its essential role in bacterial immune evasion and pathogenicity. In this work, we employed an integrated in silico pipeline to identify thioglycoside analogs structurally related to the metabolic decoys FucSBn and BacSBn, evaluating their potential to hit the UDP-galactose donor pocket of LgtC. A similarity-based screening in PubChem, followed by ADME–Tox filtering yield 18 candidate analogs. Molecular docking using AutoDock-GPU revealed several candidates, most notably C-5 (− 8.36 kcal/mol) and C-18 (− 8.13 kcal/mol), to bind favorably within the donor site, showing more negative mean scoring values than natural donor UDP-α-D-galactose (− 6.74 kcal/mol). Redocking of the natural ligand reproduced the crystallographic pose, supporting the reliability of the docking protocol. To assess dynamic behavior, 100 ns molecular dynamics simulations (AMBER14) were performed for each complex. The top-scoring analogs maintained stable binding poses, with RMSD values of ~ 2.0–3.0 Å and preserved donor-like hydrogen-bond networks complemented by π-stacking and sulfur-mediated contacts. These interaction patterns suggest that the thioglycoside analogs may occupy the donor site in a manner compatible with competitive binding. While docking and MD describe different aspects of ligand recognition, several trends observed in docking, such as the favorable binding scores of C-5 and C-18, are broadly consistent with their ability to maintain stable poses during MD. Based on this consistency and scoring, the thioglycoside scaffolds C-5, C-14, and C-18 emerge as computationally prioritized candidates for subsequent biochemical testing against LgtC. Furthermore, these scaffolds offer a mechanistic basis and putative starting points for future structure-based optimization of thioglycoside analogs aimed at disrupting LOS biosynthesis in multidrug-resistant Gram-negative bacteria.

Original language	English
Article number	13807
Journal	Scientific Reports
Volume	16
Issue number	1
DOIs	https://doi.org/10.1038/s41598-026-43638-x
State	Published - Dec 2026
Externally published	Yes

Keywords

Antivirulence strategy
Glycosyltransferase LgtC inhibition
Gram-negative bacteria
In silico drug discovery
Thioglycoside analogues

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10.1038/s41598-026-43638-x

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Sierra-Hernández, O., Saurith-Coronell, O., Alcázar, J. J., Cortés, E., Flores-Sumoza, M. C., Rodríguez-Macías, J. D., Mora, J. R., Marrero-Ponce, Y., Contreras-Torres, E., & Márquez Brazón, E. A. (2026). In silico discovery of thioglycoside analogues as donor-site inhibitors of glycosyltransferase LgtC. Scientific Reports, 16(1), Article 13807. https://doi.org/10.1038/s41598-026-43638-x

@article{bdbf7cf8770544b7a8d699421d70f577,

title = "In silico discovery of thioglycoside analogues as donor-site inhibitors of glycosyltransferase LgtC",

abstract = "The growing prevalence of multidrug-resistant Gram-negative pathogens highlights the urgent need for therapeutic strategies that complement traditional antibiotics by targeting essential virulence pathways. Glycosyltransferase LgtC, a key enzyme in lipooligosaccharide (LOS) biosynthesis, represents an attractive target for antivirulence approaches because of its essential role in bacterial immune evasion and pathogenicity. In this work, we employed an integrated in silico pipeline to identify thioglycoside analogs structurally related to the metabolic decoys FucSBn and BacSBn, evaluating their potential to hit the UDP-galactose donor pocket of LgtC. A similarity-based screening in PubChem, followed by ADME–Tox filtering yield 18 candidate analogs. Molecular docking using AutoDock-GPU revealed several candidates, most notably C-5 (− 8.36 kcal/mol) and C-18 (− 8.13 kcal/mol), to bind favorably within the donor site, showing more negative mean scoring values than natural donor UDP-α-D-galactose (− 6.74 kcal/mol). Redocking of the natural ligand reproduced the crystallographic pose, supporting the reliability of the docking protocol. To assess dynamic behavior, 100 ns molecular dynamics simulations (AMBER14) were performed for each complex. The top-scoring analogs maintained stable binding poses, with RMSD values of \textasciitilde{} 2.0–3.0 {\AA} and preserved donor-like hydrogen-bond networks complemented by π-stacking and sulfur-mediated contacts. These interaction patterns suggest that the thioglycoside analogs may occupy the donor site in a manner compatible with competitive binding. While docking and MD describe different aspects of ligand recognition, several trends observed in docking, such as the favorable binding scores of C-5 and C-18, are broadly consistent with their ability to maintain stable poses during MD. Based on this consistency and scoring, the thioglycoside scaffolds C-5, C-14, and C-18 emerge as computationally prioritized candidates for subsequent biochemical testing against LgtC. Furthermore, these scaffolds offer a mechanistic basis and putative starting points for future structure-based optimization of thioglycoside analogs aimed at disrupting LOS biosynthesis in multidrug-resistant Gram-negative bacteria.",

keywords = "Antivirulence strategy, Glycosyltransferase LgtC inhibition, Gram-negative bacteria, In silico drug discovery, Thioglycoside analogues",

author = "Olimpo Sierra-Hern{\'a}ndez and Oscar Saurith-Coronell and Alc{\'a}zar, \{Jackson J.\} and Eliceo Cort{\'e}s and Flores-Sumoza, \{Maryury C.\} and Rodr{\'i}guez-Mac{\'i}as, \{Juan D.\} and Mora, \{Jos{\'e} R.\} and Yovani Marrero-Ponce and Ernesto Contreras-Torres and \{M{\'a}rquez Braz{\'o}n\}, \{Edgar A.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = dec,

doi = "10.1038/s41598-026-43638-x",

language = "Ingl{\'e}s",

volume = "16",

journal = "Scientific Reports",

issn = "2045-2322",

publisher = "Nature Research",

number = "1",

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Sierra-Hernández, O, Saurith-Coronell, O, Alcázar, JJ, Cortés, E, Flores-Sumoza, MC, Rodríguez-Macías, JD, Mora, JR , Marrero-Ponce, Y, Contreras-Torres, E & Márquez Brazón, EA 2026, 'In silico discovery of thioglycoside analogues as donor-site inhibitors of glycosyltransferase LgtC', Scientific Reports, vol. 16, no. 1, 13807. https://doi.org/10.1038/s41598-026-43638-x

TY - JOUR

T1 - In silico discovery of thioglycoside analogues as donor-site inhibitors of glycosyltransferase LgtC

AU - Sierra-Hernández, Olimpo

AU - Saurith-Coronell, Oscar

AU - Alcázar, Jackson J.

AU - Cortés, Eliceo

AU - Flores-Sumoza, Maryury C.

AU - Rodríguez-Macías, Juan D.

AU - Mora, José R.

AU - Marrero-Ponce, Yovani

AU - Contreras-Torres, Ernesto

AU - Márquez Brazón, Edgar A.

N1 - Publisher Copyright: © The Author(s) 2026.

PY - 2026/12

Y1 - 2026/12

N2 - The growing prevalence of multidrug-resistant Gram-negative pathogens highlights the urgent need for therapeutic strategies that complement traditional antibiotics by targeting essential virulence pathways. Glycosyltransferase LgtC, a key enzyme in lipooligosaccharide (LOS) biosynthesis, represents an attractive target for antivirulence approaches because of its essential role in bacterial immune evasion and pathogenicity. In this work, we employed an integrated in silico pipeline to identify thioglycoside analogs structurally related to the metabolic decoys FucSBn and BacSBn, evaluating their potential to hit the UDP-galactose donor pocket of LgtC. A similarity-based screening in PubChem, followed by ADME–Tox filtering yield 18 candidate analogs. Molecular docking using AutoDock-GPU revealed several candidates, most notably C-5 (− 8.36 kcal/mol) and C-18 (− 8.13 kcal/mol), to bind favorably within the donor site, showing more negative mean scoring values than natural donor UDP-α-D-galactose (− 6.74 kcal/mol). Redocking of the natural ligand reproduced the crystallographic pose, supporting the reliability of the docking protocol. To assess dynamic behavior, 100 ns molecular dynamics simulations (AMBER14) were performed for each complex. The top-scoring analogs maintained stable binding poses, with RMSD values of ~ 2.0–3.0 Å and preserved donor-like hydrogen-bond networks complemented by π-stacking and sulfur-mediated contacts. These interaction patterns suggest that the thioglycoside analogs may occupy the donor site in a manner compatible with competitive binding. While docking and MD describe different aspects of ligand recognition, several trends observed in docking, such as the favorable binding scores of C-5 and C-18, are broadly consistent with their ability to maintain stable poses during MD. Based on this consistency and scoring, the thioglycoside scaffolds C-5, C-14, and C-18 emerge as computationally prioritized candidates for subsequent biochemical testing against LgtC. Furthermore, these scaffolds offer a mechanistic basis and putative starting points for future structure-based optimization of thioglycoside analogs aimed at disrupting LOS biosynthesis in multidrug-resistant Gram-negative bacteria.

AB - The growing prevalence of multidrug-resistant Gram-negative pathogens highlights the urgent need for therapeutic strategies that complement traditional antibiotics by targeting essential virulence pathways. Glycosyltransferase LgtC, a key enzyme in lipooligosaccharide (LOS) biosynthesis, represents an attractive target for antivirulence approaches because of its essential role in bacterial immune evasion and pathogenicity. In this work, we employed an integrated in silico pipeline to identify thioglycoside analogs structurally related to the metabolic decoys FucSBn and BacSBn, evaluating their potential to hit the UDP-galactose donor pocket of LgtC. A similarity-based screening in PubChem, followed by ADME–Tox filtering yield 18 candidate analogs. Molecular docking using AutoDock-GPU revealed several candidates, most notably C-5 (− 8.36 kcal/mol) and C-18 (− 8.13 kcal/mol), to bind favorably within the donor site, showing more negative mean scoring values than natural donor UDP-α-D-galactose (− 6.74 kcal/mol). Redocking of the natural ligand reproduced the crystallographic pose, supporting the reliability of the docking protocol. To assess dynamic behavior, 100 ns molecular dynamics simulations (AMBER14) were performed for each complex. The top-scoring analogs maintained stable binding poses, with RMSD values of ~ 2.0–3.0 Å and preserved donor-like hydrogen-bond networks complemented by π-stacking and sulfur-mediated contacts. These interaction patterns suggest that the thioglycoside analogs may occupy the donor site in a manner compatible with competitive binding. While docking and MD describe different aspects of ligand recognition, several trends observed in docking, such as the favorable binding scores of C-5 and C-18, are broadly consistent with their ability to maintain stable poses during MD. Based on this consistency and scoring, the thioglycoside scaffolds C-5, C-14, and C-18 emerge as computationally prioritized candidates for subsequent biochemical testing against LgtC. Furthermore, these scaffolds offer a mechanistic basis and putative starting points for future structure-based optimization of thioglycoside analogs aimed at disrupting LOS biosynthesis in multidrug-resistant Gram-negative bacteria.

KW - Antivirulence strategy

KW - Glycosyltransferase LgtC inhibition

KW - Gram-negative bacteria

KW - In silico drug discovery

KW - Thioglycoside analogues

UR - https://www.scopus.com/pages/publications/105037600439

U2 - 10.1038/s41598-026-43638-x

DO - 10.1038/s41598-026-43638-x

M3 - Artículo

C2 - 41844697

AN - SCOPUS:105037600439

SN - 2045-2322

VL - 16

JO - Scientific Reports

JF - Scientific Reports

IS - 1

M1 - 13807

ER -

In silico discovery of thioglycoside analogues as donor-site inhibitors of glycosyltransferase LgtC

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Keywords

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