AI Article Synopsis
- Multidrug-resistant ESKAPE pathogens are major culprits behind hospital-acquired infections, resulting from genetic mutations and widespread antibiotic exposure, leading to dangerous strains that resist treatment.
- Identifying new antimicrobial targets and understanding bacterial pathways, particularly the role of kinases in survival and immunity evasion, is crucial for developing effective therapies.
- The review also highlights the importance of biofilms in ESKAPE pathogen survival and summarizes ongoing research on therapeutic options that target ESKAPE kinases.
Article Abstract
Multidrug-resistant ESKAPE pathogens are the leading cause of hospital-acquired infections across the globe, posing challenges for clinicians. Random genetic mutations and constant exposure to antibiotics in healthcare settings result in strains resistant to commonly used antibiotics, creating life-threatening conditions. If the magic of "antibiotics" is to be sustained, a new class of antimicrobials against novel targets is urgently needed. This necessitates understanding and identifying novel biochemical pathways and bacterial virulence factors that can be targeted for therapeutic interventions. Keeping in view the unambiguous role of the kinome in bacterial survival and virulence, this review provides a survey of effector bacterial kinases involved in evading host immune responses and drug resistance. The formation of biofilms is a critical feature associated with the pathogenesis and survival of ESKAPE organisms in the hostile host milieu. Hence, kinases involved in the biofilm pathway are also elucidated for clinical relevance. In addition, endeavors in the development of therapeutics against ESKAPE kinases are also summarized to provide direction to researchers pursuing the field.
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| http://dx.doi.org/10.2174/0118715257267497231128093529 | DOI Listing |
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