Molecular mechanisms of alarmones during bacterial stress responses

Molecular mechanisms of alarmones during bacterial stress responses

In the incessant effort of living and propagating, bacterial cells cope with environmental stress via the release of second messengers and/or alarmones that allow them to adapt swiftly. Such molecules are nucleotidebased and can be promptly generated when stress stimuli occur. According to the c...

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Gorde:
Xehetasun bibliografikoak
Egile nagusia: Giammarinaro, Pietro Ivan
Beste egile batzuk: Bange, Gert (PhD, Professor) (Tesi aholkularia)
Formatua: Dissertation
Hizkuntza:ingelesa
Argitaratua: Philipps-Universität Marburg 2023
Gaiak:
Chemie
Biochemistry and Structural biology
Chemistry & allied sciences
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Deskribapena
Gaia:In the incessant effort of living and propagating, bacterial cells cope with environmental stress via the release of second messengers and/or alarmones that allow them to adapt swiftly. Such molecules are nucleotidebased and can be promptly generated when stress stimuli occur. According to the cellular concentration of stress mediators, specific molecular targets would be activated to modulate vital processes for bacterial survival and proliferation. As soon as the stress is over, cells would repristinate the initial concentration of the stress-coping mediators with deputed enzymes. Overall, the aforementioned mechanisms fall in the definition of Bacterial Stress Response (BSF). The aim of the present doctoral thesis is to illustrate and discuss three published scientific articles that contributed to the understanding of the BSF in bacterial cells and the role of the stress mediators 5',5'''-diadenosine tetraphosphate (Ap4A) and ppGpp and pppGpp (collectively (p)ppGpp). The Publication #1 described how Ap4A could restrict the activity of the essential enzyme inosine monophosphate dehydrogenase (IMPDH) in Bacillus subtilis in order to reprogram the levels of purine nucleotides during heat shock. The present publication proposed IMPDH as the first physiologically confirmed target of Ap4A in prokaryotes and characterized the molecular mechanisms of how Ap4A inhibits IMPDH. The biological relevance of the interaction Ap4A-IMPDH was further analyzed and proven with in vivo experiments.
DOI:10.17192/z2023.0525

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