# Beyond mecA: a two-tiered mechanism and regulatory rewiring drive high-level ceftaroline resistance in clinical MRSA

**Authors:** Melissa Sassman, Michele Karolak, Margeurite Dallaire, Claire E. Schaffer, Carlos Gartner, Calvin Vary, Roberto R. Rosato, Adriana E. Rosato

PMC · DOI: 10.1128/aac.00586-25 · Antimicrobial Agents and Chemotherapy · 2026-01-07

## TL;DR

MRSA can develop high resistance to ceftaroline through a new mechanism involving gene mutations and regulatory changes, not just the known mecA pathway.

## Contribution

Discovers a two-step resistance mechanism in MRSA involving rpoB mutations and regulatory rewiring, independent of mecA.

## Key findings

- High-level ceftaroline resistance in MRSA can emerge via a collateral pathway triggered by carbapenems.
- Mutations in rpoB and pbp1 (H499R) along with mecA variants are linked to resistance.
- Elevated Spx and TrfA levels stabilize resistance through c-di-AMP regulation.

## Abstract

High-level resistance to ceftaroline, a fifth-generation β-lactam critical for treating methicillin-resistant Staphylococcus aureus (MRSA), is an emerging threat to global health. While resistance is traditionally attributed to mecA-mediated expression of PBP2a, our study reveals a previously unrecognized mechanism. We show that high-level resistance to ceftaroline can arise independently of ceftaroline exposure through a collateral pathway triggered by carbapenems typically used to treat Gram-negative infections. Our findings reveal a two-tiered adaptive process. First, meropenem selects non-synonymous mutations in rpoB, a core transcriptional regulator, which primes resistance by reprogramming gene expression. These changes consistently co-occur with a key substitution in pbp1 (H499R), an essential protein for cell division, and specific mecA variants (Y446H, E447K) following ceftaroline exposure. Second, resistance is stabilized through regulatory and signaling adaptations, with elevated basal levels of the oxidative stress regulator Spx and its adaptor protein TrfA supporting the altered cellular state. Proteomic and biophysical studies revealed direct binding of TrfA to GdpP, the phosphodiesterase for cyclic-di-AMP, linking this regulatory circuit to elevated c-di-AMP levels and resistance maintenance. Our findings challenge the assumption that ceftaroline resistance is driven solely by PBP2a alterations and reveal how collateral resistance pathways can be activated by broad-spectrum antibiotic use. This study highlights the evolutionary capacity of MRSA to circumvent antibiotic pressure and underscores the need for improved antimicrobial stewardship.

## Linked entities

- **Genes:** mecA (adaptor protein controlling oligomerization of the AAA+ protein ClpC) [NCBI Gene 936406], rpoB (RNA polymerase beta subunit) [NCBI Gene 800292], PBP1 (PYK10-binding protein 1) [NCBI Gene 820890], SPX (spexin hormone) [NCBI Gene 80763], trfA (hypothetical protein) [NCBI Gene 8617028], gdpP (phosphodiesterase acting on cyclic dinucleotides) [NCBI Gene 937816]
- **Proteins:** pbp2a (penicillin-binding protein PBP2A), trfA (hypothetical protein), gdpP (phosphodiesterase acting on cyclic dinucleotides)
- **Chemicals:** ceftaroline (PubChem CID 9852981), meropenem (PubChem CID 441130)
- **Diseases:** MRSA (MONDO:0100073)
- **Species:** Staphylococcus aureus (taxon 1280)

## Full-text entities

- **Diseases:** Gram-negative infections (MESH:D016905)
- **Chemicals:** mecA (MESH:C046756), c-di-AMP (MESH:C528998), meropenem (MESH:D000077731), carbapenems (MESH:D015780), methicillin (MESH:D008712), beta-lactam (MESH:D047090), ceftaroline (MESH:C490727)
- **Species:** Staphylococcus aureus (species) [taxon 1280]
- **Mutations:** E447K, Y446H, H499R

## Full text

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## Figures

9 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12888875/full.md

## References

39 references — full list in the complete paper: https://tomesphere.com/paper/PMC12888875/full.md

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Source: https://tomesphere.com/paper/PMC12888875