SUMMARY
Programmed cell death (PCD) is crucial for development and homeostasis of all multicellular organisms. In human cells, the double role of extra‐mitochondrial cytochrome c in triggering ...apoptosis and inhibiting survival pathways is well reported. In plants, however, the specific role of cytochrome c upon release from the mitochondria remains in part veiled yet death stimuli do trigger cytochrome c translocation as well. Here, we identify an Arabidopsis thaliana 14‐3‐3ι isoform as a cytosolic cytochrome c target and inhibitor of caspase‐like activity. This finding establishes the 14‐3‐3ι protein as a relevant factor at the onset of plant H2O2‐induced PCD. The in vivo and in vitro studies herein reported reveal that the interaction between cytochrome c and 14‐3‐3ι exhibits noticeable similarities with the complex formed by their human orthologues. Further analysis of the heterologous complexes between human and plant cytochrome c with plant 14‐3‐3ι and human 14‐3‐3ε isoforms corroborated common features. These results suggest that cytochrome c blocks p14‐3‐3ι so as to inhibit caspase‐like proteases, which in turn promote cell death upon H2O2 treatment. Besides establishing common biochemical features between human and plant PCD, this work sheds light onto the signaling networks of plant cell death.
Significance Statement
Common features of the cytochrome c‐dependent pathways leading to programmed cell death in plants and humans are herein revealed. In response to oxidative stress, cytochrome c is released from mitochondria to the cytoplasm to hamper the iota isoform of the 14‐3‐3 protein family, thereby decreasing the inhibition of caspase‐like activity and likely contributing to promote cell death in plants.
Cytochrome c (Cc) is a protein that functions as an electron carrier in the mitochondrial respiratory chain. However, Cc has moonlighting roles outside mitochondria driving the transition of ...apoptotic cells from life to death. When living cells are damaged, Cc escapes its natural mitochondrial environment and, once in the cytosol, it binds other proteins to form a complex named the apoptosome—a platform that triggers caspase activation and further leads to controlled cell dismantlement. Early released Cc also binds to inositol 1,4,5‐triphosphate receptors on the ER membrane, which stimulates further massive Cc release from mitochondria. Besides the well‐characterized binding proteins contributing to the proapoptotic functions of Cc, many novel protein targets have been recently described. Among them, histone chaperones were identified as key partners of Cc following DNA breaks, indicating that Cc might modulate chromatin dynamics through competitive binding to histone chaperones. In this article, we review the ample set of recently discovered antiapoptotic proteins—involved in DNA damage, transcription, and energetic metabolism—reported to interact with Cc in the cytoplasm and even the nucleus upon DNA breaks.
The IUBMB Focused Meeting/FEBS Workshop titled ‘Crosstalk between Nucleus and Mitochondria in Human Disease‘(CrossMitoNus) will take place on September 7–10, 2021 in Seville (Spain), with the support ...of both the International Union of Biochemistry and Molecular Biology (IUBMB) and the Federation of European Biochemical Societies (FEBS). Mitochondria are key organelles that act as a hub for vital metabolic processes, for example, energy transduction by oxidative phosphorylation, intermediary metabolism, redox signaling, calcium and iron homeostasis, heme and steroid biosynthesis, metal homeostasis, programmed cell death, and innate immunity. Consequently, a wide assortment of diseases—including neurodegenerative disorders, diabetes, cancer, rare syndromes, and many others—relate to mitochondrial dysfunction. The high relevance of mitochondria in metabolism centers on the core of cell signaling pathways, including those involved in cell‐fate decisions. Critical metabolites synthesized in mitochondria are, for instance, key modulators of the sirtuin, AMPK, mTOR, and Hypoxia‐inducible Factor 1A pathways. Mitochondria are indeed the major source of reactive oxygen species, which in turn mediate several regulatory routes. Interestingly, multiple nuclear‐encoded factors control essential processes in mitochondrial dynamics, namely fusion (for instance, OPA1), fission (DNM1L), transport (RHOT1), and mitophagy (PINK1). The release of mitochondrial factors like cytochrome c to the cytoplasm is indeed key for the rapid onset of the intrinsic apoptotic pathway. The CrossMitoNus meeting aims to join efforts from diverse disciplines to unveil the mitochondrial and nuclear factors that are emerging as essential elements in mitochondria‐nucleus communication. Needless to say, the mechanisms regulating mitochondrial protein trafficking into and out of the nucleus and the role of these proteins in the nucleus remain to be elucidated.
•Respiratory chain organization is highly dynamic and adapts to cellular needs.•Supercomplex formation facilitates cytochrome c 2D sliding from complex III to IV.•Physical contact contributes to ...redox potential gap and electron transfer.•Long-distance electron transfer allows a faster turnover of cytochrome c.
The supramolecular arrangement of respiratory complexes into supercomplexes is widely accepted. The common feature observed in the supercomplex architecture from organisms of diverse phylogenetic origin is the reduction of the distance between cytochrome bc1 (complex III) and cytochrome c oxidase (complex IV). Such an arrangement reduces the dimensionality (from 3D to 2D) of the diffusional search of cytochrome c as the electron carrier that connects both complexes. In this scenario, our recent finding of additional binding sites for cytochrome c reinforces the concept of a “restrained 2D sliding pathway” onto the supercomplex surface. Herein, we analyze novel mechanistic insights into electron transfer towards cytochrome c, including modulation of the redox potential by physical contact as well as gated, long-range electron transfer through an aqueous solution. These data establish a new horizon for the understanding of electron transfer mechanisms beyond unique and well-orientated protein complexes. Multiple and dynamic long-distance conformational ensembles compatible with electron transfer could indeed contribute to the rapid adjustment of electron flow in response to changing cellular conditions.
Higher-order plants and mammals use similar mechanisms to repair and tolerate oxidative DNA damage. Most studies on the DNA repair process have focused on yeast and mammals, in which histone ...chaperone-mediated nucleosome disassembly/reassembly is essential for DNA to be accessible to repair machinery. However, little is known about the specific role and modulation of histone chaperones in the context of DNA damage in plants. Here, the histone chaperone NRP1, which is closely related to human SET/TAF-Iβ, was found to exhibit nucleosome assembly activity in vitro and to accumulate in the chromatin of Arabidopsis thaliana after DNA breaks. In addition, this work establishes that NRP1 binds to cytochrome c, thereby preventing the former from binding to histones. Since NRP1 interacts with cytochrome c at its earmuff domain, that is, its histone-binding domain, cytochrome c thus competes with core histones and hampers the activity of NRP1 as a histone chaperone. Altogether, the results obtained indicate that the underlying molecular mechanisms in nucleosome disassembly/reassembly are highly conserved throughout evolution, as inferred from the similar inhibition of plant NRP1 and human SET/TAF-Iβ by cytochrome c during DNA damage response.
Regulation of mitochondrial activity allows cells to adapt to changing conditions and to control oxidative stress, and its dysfunction can lead to hypoxia-dependent pathologies such as ischemia and ...cancer. Although cytochrome c phosphorylation—in particular, at tyrosine 48—is a key modulator of mitochondrial signaling, its action and molecular basis remain unknown. Here we mimic phosphorylation of cytochrome c by replacing tyrosine 48 with p-carboxy-methyl-L-phenylalanine (pCMF). The NMR structure of the resulting mutant reveals significant conformational shifts and enhanced dynamics around pCMF that could explain changes observed in its functionality: The phosphomimetic mutation impairs cytochrome c diffusion between respiratory complexes, enhances hemeprotein peroxidase and reactive oxygen species scavenging activities, and hinders caspase-dependent apoptosis. Our findings provide a framework to further investigate the modulation of mitochondrial activity by phosphorylated cytochrome c and to develop novel therapeutic approaches based on its prosurvival effects.
Chromatin is pivotal for regulation of the DNA damage process insofar as it influences access to DNA and serves as a DNA repair docking site. Recent works identify histone chaperones as key ...regulators of damaged chromatin's transcriptional activity. However, understanding how chaperones are modulated during DNA damage response is still challenging. This study reveals that the histone chaperone SET/TAF-Iβ interacts with cytochrome c following DNA damage. Specifically, cytochrome c is shown to be translocated into cell nuclei upon induction of DNA damage, but not upon stimulation of the death receptor or stress-induced pathways. Cytochrome c was found to competitively hinder binding of SET/TAF-Iβ to core histones, thereby locking its histone-binding domains and inhibiting its nucleosome assembly activity. In addition, we have used NMR spectroscopy, calorimetry, mutagenesis, and molecular docking to provide an insight into the structural features of the formation of the complex between cytochrome c and SET/TAF-Iβ. Overall, these findings establish a framework for understanding the molecular basis of cytochrome c-mediated blocking of SET/TAF-Iβ, which subsequently may facilitate the development of new drugs to silence the oncogenic effect of SET/TAF-Iβ's histone chaperone activity.
Cyclin M (CNNM1-4) proteins maintain cellular and body magnesium (Mg
2+
) homeostasis. Using various biochemical approaches, we have identified members of the CNNM family as direct interacting ...partners of ADP-ribosylation factor-like GTPase 15 (ARL15), a small GTP-binding protein. ARL15 interacts with CNNMs at their carboxyl-terminal conserved cystathionine-β-synthase (CBS) domains.
In silico
modeling of the interaction between CNNM2 and ARL15 supports that the small GTPase specifically binds the CBS1 and CNBH domains. Immunocytochemical experiments demonstrate that CNNM2 and ARL15 co-localize in the kidney, with both proteins showing subcellular localization in the endoplasmic reticulum, Golgi apparatus and the plasma membrane. Most importantly, we found that ARL15 is required for forming complex N-glycosylation of CNNMs. Overexpression of ARL15 promotes complex N-glycosylation of CNNM3. Mg
2+
uptake experiments with a stable isotope demonstrate that there is a significant increase of
25
Mg
2+
uptake upon knockdown of ARL15 in multiple kidney cancer cell lines. Altogether, our results establish ARL15 as a novel negative regulator of Mg
2+
transport by promoting the complex N-glycosylation of CNNMs.
Respiratory cytochrome c has been found to be phosphorylated at tyrosine 97 in the postischemic brain upon neuroprotective insulin treatment, but how such posttranslational modification affects ...mitochondrial metabolism is unclear. Here, we report the structural features and functional behavior of a phosphomimetic cytochrome c mutant, which was generated by site-specific incorporation at position 97 of p-carboxymethyl-L-phenylalanine using the evolved tRNA synthetase method. We found that the point mutation does not alter the overall folding and heme environment of cytochrome c, but significantly affects the entire oxidative phosphorylation process. In fact, the electron donation rate of the mutant heme protein to cytochrome c oxidase, or complex IV, within respiratory supercomplexes was higher than that of the wild-type species, in agreement with the observed decrease in reactive oxygen species production. Direct contact of cytochrome c with the respiratory supercomplex factor HIGD1A (hypoxia-inducible domain family member 1A) is reported here, with the mutant heme protein exhibiting a lower affinity than the wild-type species. Interestingly, phosphomimetic cytochrome c also exhibited a lower caspase-3 activation activity. Altogether, these findings yield a better understanding of the molecular basis for mitochondrial metabolism in acute diseases, such as brain ischemia, and thus could allow the use of phosphomimetic cytochrome c as a neuroprotector with therapeutic applications.
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