Early life stress induces dysregulation of the heme pathway in adult mice

Pettway, Yasminye D.; Neder, Thomas H.; Ho, Dao H.; Fox, Brandon; Burch, Mariah; Colson, Jackson; Liu, Xiaofen; Kellum, Cailin E.; Hyndman, Kelly A.; Pollock, Jennifer S.

doi:10.14814/phy2.14844

Cited by 1 publication

(1 citation statement)

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“…Nevertheless, the observation of larger multimers does appear to be heme concentration dependent. This observation is particularly relevant when considered within the context of physiological stress which can result in excess production of heme. , Under these conditions, this work suggests that PGRMC1 would predominantly exist in a dimeric state. Thus, if the PGRMC1 dimer is indeed required for downstream PPIs, then such conditions would likely facilitate interactions with cytochrome P450s.…”

Section: Discussionmentioning

confidence: 99%

Defining Requirements for Heme Binding in PGRMC1 and Identifying Key Elements that Influence Protein Dimerization

Badve,

Meier

2024

Biochemistry

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Progesterone receptor membrane component 1 (PGRMC1) binds heme via a surface-exposed site and displays some structural resemblance to cytochrome b5 despite their different functions. In the case of PGRMC1, it is the protein interaction with drug-metabolizing cytochrome P450s and the epidermal growth factor receptor that has garnered the most attention. These interactions are thought to result in a compromised ability to metabolize common chemotherapy agents and to enhance cancer cell proliferation. X-ray crystallography and immunoprecipitation data have suggested that heme-mediated PGRMC1 dimers are important for facilitating these interactions. However, more recent studies have called into question the requirement of heme binding for PGRMC1 dimerization. Our study employs spectroscopic and computational methods to probe and define heme binding and its impact on PGRMC1 dimerization. Fluorescence, electron paramagnetic resonance and circular dichroism spectroscopies confirm heme binding to apo-PGRMC1 and were used to demonstrate the stabilizing effect of heme on the wild-type protein. We also utilized variants (C129S and Y113F) to precisely define the contributions of disulfide bonds and direct heme coordination to PGRMC1 dimerization. Understanding the key factors involved in these processes has important implications for downstream protein−protein interactions that may influence the metabolism of chemotherapeutic agents. This work opens avenues for deeper exploration into the physiological significance of the truncated-PGRMC1 model and developing design principles for potential therapeutics to target PGRMC1 dimerization and downstream interactions.

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Section: Discussionmentioning

confidence: 99%