Bayan Mashahreh scite author profile

Ubiquitylation controls protein function and degradation. Therefore, ubiquitin ligases need to be tightly controlled. We discovered an evolutionarily conserved allosteric restraint mechanism for Nedd4 ligases and demonstrated its function with diverse substrates: the yeast soluble proteins Rpn10 and Rvs167, and the human receptor tyrosine kinase FGFR1 and cardiac I potassium channel. We found that a potential trimerization interface is structurally blocked by the HECT domain α1-helix, which further undergoes ubiquitylation on a conserved lysine residue. Genetic, bioinformatics, biochemical and biophysical data show that attraction between this α1-conjugated ubiquitin and the HECT ubiquitin-binding patch pulls the α1-helix out of the interface, thereby promoting trimerization. Strikingly, trimerization renders the ligase inactive. Arginine substitution of the ubiquitylated lysine impairs this inactivation mechanism and results in unrestrained FGFR1 ubiquitylation in cells. Similarly, electrophysiological data and TIRF microscopy show that NEDD4 unrestrained mutant constitutively downregulates the I channel, thus confirming the functional importance of E3-ligase autoinhibition.

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Novel insights into the interaction of UBA5 with UFM1 via a UFM1-interacting sequence

Padala¹,

Oweis²,

Mashahreh³

et al. 2017

Sci Rep

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The modification of proteins by ubiquitin-fold modifier 1 (UFM1) is implicated in many human diseases. Prior to conjugation, UFM1 undergoes activation by its cognate activating enzyme, UBA5. UBA5 is a non-canonical E1 activating enzyme that possesses an adenylation domain but lacks a distinct cysteine domain. Binding of UBA5 to UFM1 is mediated via an amino acid sequence, known as the UFM1-interacting sequence (UIS), located outside the adenylation domain that is required for UFM1 activation. However, the precise boundaries of the UIS are yet not clear and are still under debate. Here we revisit the interaction of UFM1 with UBA5 by determining the crystal structure of UFM1 fused to 13 amino acids of human UBA5. Using binding and activity assays, we found that His 336 of UBA5, previously not reported to be part of the UIS, occupies a negatively charged pocket on UFM1’s surface. This His is involved in UFM1 binding and if mutated perturbs activation of UFM1. Surprisingly, we also found that the interaction between two UFM1 molecules mimics how the UIS binds UFM1. Specifically, UFM1 His 70 resembles UBA5 His336 and enters a negatively charged pocked on the other UFM1 molecule. Our results refine our understanding of UFM1-UBA5 binding.

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An N-Terminal Extension to UBA5 Adenylation Domain Boosts UFM1 Activation: Isoform-Specific Differences in Ubiquitin-like Protein Activation

Soudah¹,

Padala²,

Hassouna³

et al. 2019

Journal of Molecular Biology

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Modification of proteins by the ubiquitin-like protein, UFM1, requires activation of UFM1 by the E1-activating enzyme, UBA5. In humans UBA5 possesses two isoforms, each comprising an adenylation domain, but only one containing an N-terminal extension.Currently the role of the N-terminal extension in UFM1 activation is not clear. Here we provide structural and biochemical data on UBA5 N-terminal extension to understand its contribution to UFM1 activation. The crystal structures of the UBA5 long isoform bound to ATP with and without UFM1 show that the N-terminus not only is directly involved in ATP binding, but also affects how the adenylation domain interacts with ATP.Surprisingly, in the presence of the N-terminus, UBA5 no longer retains the 1:2 ratio of ATP to UBA5, but rather this becomes a 1:1 ratio. Accordingly, the N-terminus significantly increases the affinity of ATP to UBA5. Finally, the N-terminus, although not directly involved in the E2 binding, stimulates transfer of UFM1 from UBA5 to the E2, UFC1.

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Conserved degronome features governing quality control associated proteolysis

Mashahreh

Armony

Johansson

et al. 2022

Preprint

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SummaryThe eukaryotic proteome undergoes constant surveillance by quality control systems that either sequester, refold, or eliminate aberrant proteins by ubiquitin-dependent mechanisms. Ubiquitin-conjugation necessitates the recognition of degradation determinants, termed degrons, by their cognate E3 ubiquitin-protein ligases. To learn about the distinctive properties of quality control degrons, we performed an unbiased peptidome stability screen in yeast. The search identified a large cohort of proteome-derived degrons., some of which exhibited broad E3 ligase specificity. Consequent application of a machine-learning algorithm established constraints governing degron potency, including the amino acids composition and secondary structure propensities. According to the set criteria, degrons with transmembrane domain-like characteristics are the most probable sequences to act as degrons. Similar quality control degrons were identified in viral and human proteins, suggesting for conserved degradation mechanisms. Altogether, the emerging data indicate that transmembrane domain-like degron features have been preserved in evolution as key quality control determinants of proteins’ half-life.

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Prediction of quality-control degradation signals in yeast proteins

Johansson

Mashahreh

Hartmann‐Petersen

et al. 2022

Preprint

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Effective proteome homeostasis is key to cellular and organismal survival, and cells therefore contain efficient quality control systems to monitor and remove potentially toxic misfolded proteins. Such general protein quality control to a large extent relies on the efficient and robust delivery of misfolded or unfolded proteins to the ubiquitin-proteasome system. This is achieved via recognition of so-called degradation motifs-degrons-that are assumed to become exposed as a result of protein misfolding. Despite their importance, the nature and sequence properties of quality-control degrons remain elusive. Here, we have used data from a yeast-based screen of 23,600 17-residue peptides to build a predictor of quality-control degrons. The resulting model, QCDPred (Quality Control Degron Prediction), achieves good accuracy using only the sequence composition of the peptides as input. Our analysis reveals that strong degrons are enriched in hydrophobic amino acids and depleted in negatively charged amino acids, in line with the expectation that they are buried in natively folded proteins. We applied QCDPred to the entire yeast proteome, enabling us to analyse more widely the potential effects of degrons. As an example, we show a correlation between cellular abundance and degron potential in disordered regions of proteins. Together with recent results on membrane proteins, our work suggest that the recognition of exposed hydrophobic residues is a key and generic mechanism for proteome homeostasis.

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Bayan Mashahreh

Ubiquitylation‐dependent oligomerization regulates activity of Nedd4 ligases

Novel insights into the interaction of UBA5 with UFM1 via a UFM1-interacting sequence

An N-Terminal Extension to UBA5 Adenylation Domain Boosts UFM1 Activation: Isoform-Specific Differences in Ubiquitin-like Protein Activation

Conserved degronome features governing quality control associated proteolysis

Prediction of quality-control degradation signals in yeast proteins

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