Structure-based mechanism of preferential complex formation by apoptosis signal–regulating kinases

Trevelyan, Sarah J; Brewster, Jodi L.; Burgess, Abigail E.; Crowther, Jennifer M.; Cadell, Antonia L; Parker, Benjamin L.; Croucher, David R.; Dobson, Renwick C. J.; Murphy, James M.; Mace, Peter D.

doi:10.1126/scisignal.aay6318

Cited by 22 publications

(23 citation statements)

References 69 publications

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“…S2A): two intrinsically disordered regions (IDRs; Fig. S2B), one coiled-coil domain (CC), one sterile alpha motif domain (SAM) ( 25 ) and one low complexity region (LCR). Between ASK3 CT mutants with these deletions, CTΔCC, CTΔSAM and CTΔLCR exhibited reduced condensation ability compared with the original CT (Fig.…”

Section: Resultsmentioning

confidence: 99%

Cells recognize osmotic stress through liquid-liquid phase separation lubricated with poly(ADP-ribose)

Watanabe

Morishita

Zhou

et al. 2020

Preprint

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21Cells are under threat of osmotic perturbation; and cell volume maintenance is critical in 22 cerebral edema, inflammation and aging, in which prominent changes in intracellular or 23 extracellular osmolality emerge. After osmotic stress-enforced cell swelling or shrinkage, 24 the cells regulate intracellular osmolality to recover their volume. However, the 25 mechanisms recognizing osmotic stress remain obscured. We previously clarified that 26 apoptosis signal-regulating kinase 3 (ASK3) bidirectionally responds to osmotic stress 27 and regulates cell volume recovery. Here, we report that macromolecular crowding 28 induces liquid-demixing condensates of ASK3 under hyperosmotic stress, which 29 transduce osmosensing signal into ASK3 inactivation. A genome-wide small interfering 30 RNA (siRNA) screen identified an ASK3 inactivation regulator, nicotinamide 31 phosphoribosyltransferase (NAMPT), related to poly(ADP-ribose) signaling. 32 Furthermore, we clarify that poly(ADP-ribose) keeps ASK3 condensates in the liquid 33 phase and enables ASK3 to become inactivated under hyperosmotic stress. Our findings 34 demonstrate that cells rationally incorporate physicochemical phase separation into their 35 osmosensing systems. 36 37 38

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Section: Resultsmentioning

confidence: 99%

Cells recognize osmotic stress through liquid-liquid phase separation lubricated with poly(ADP-ribose)

Watanabe

Morishita

Zhou

et al. 2020

Preprint

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“…First, we coexpressed the KD of ASK1 with a PKA catalytic subunit, but the KD failed to be activated, whereas full-length ASK1 was activated, suggesting that the N-terminus and/or C-terminus are required for activation (Fig 2D). Next, we focused on the C-terminal region, which harbors a predicted C-terminal coiled-coil (CCC) domain [34] and a sterile-alpha motif (SAM) domain [45], which is essential for high-order oligomerization of ASK1. Interestingly, exogenously expressed PKA did not activate both ⊿C and ⊿CCC of ASK1 (Fig 2E), which indicates that the C-terminal regulatory region, specifically a domain for homo-oligomerization, is a prerequisite for PKA-dependent ASK1 activation.…”

Section: Resultsmentioning

confidence: 99%

“…In the previous analysis, we discovered that ASK1 forms a high molecular mass signaling complex (>MDa, compared to ~150 kDa for the monomer) [53], and subsequent studies have shed light on a wide variety of components of this complex [28,45], including ASK2, a member of the ASK family. ASK2 tightly forms a heteromeric complex with ASK1 and supports ASK1 kinase activity [25].…”

Section: Resultsmentioning

confidence: 99%

“…Ser 993 is retained in the ⊿CCC of ASK1, but the ⊿CCC loses its ability to be activated by PKA (Fig 2E), which suggests that both phospho-ASK1 Ser 993 and CCC-mediated homo-oligomerization are required for its activation; however, the mutual interaction of these two phenomena is still unknown. A recent study suggested that the SAM domain is located on the C-terminal side of the CCC and is critical for oligomerization [45]; hence, the effects of S993A and the ⊿CCC on the SAM domain structure should also be considered. Notably, we could not find similar sequences around mouse ASK1 Thr 99 or Ser 993 in mouse ASK2, suggesting that PKA differentially regulates ASK2.…”

Section: Discussionmentioning

confidence: 99%

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β-adrenergic receptor signaling evokes the PKA-ASK axis in mature brown adipocytes

Hattori

Wakatsuki

Sakauchi

et al. 2020

Preprint

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21Boosting energy expenditure by harnessing the activity of brown adipocytes is a promising 22 strategy for combatting the global epidemic of obesity. Many studies have revealed that the β3-adrenergic 23 receptor agonist is a potent activator of brown adipocytes, even in humans, and PKA and p38 MAPK have 24 been demonstrated for regulating the transcription of a wide range of critical genes such as Ucp1. We 25 previously revealed that the PKA-ASK1-p38 axis is activated in immature brown adipocytes and 26 contributes to functional maturation. However, the downstream mechanisms of PKA that initiate the p38 27 MAPK cascade are still mostly unknown in mature brown adipocytes. Here, we identified the ASK family 28 as a crucial signaling molecule bridging PKA and MAPK in mature brown adipocytes. Mechanistically, the 29 phosphorylation of ASK1 at threonine 99 and serine 993 is critical in PKA-dependent ASK1 activation. 30Additionally, PKA also activates ASK2, which contributes to MAPK regulation. These lines of evidence 31 provide new details for tailoring a βAR-dependent brown adipocyte activation strategy. 32 and the approved dose exhibits only limited effects; hence, off-target effects of β3AR agonists and cross-57 activation of β1AR and β2AR should be considered. Clinically, constructing selective methods for activating 58 β3AR on brown and/or beige adipocytes is crucial, but it is of critical importance to understand the signaling 59 mechanisms induced by β3AR agonists in mature brown adipocytes to fully understand the potential side 60 effects of β3AR agonism. However, a limited number of studies have uncovered the involvement of several 61 kinases in β3AR signaling [16][17][18][19]; specifically, the downstream targets of PKA are not fully known. 62Among a wide variety of signaling pathways, the stress-responsive mitogen-activated protein 63 kinase (MAPK) pathway regulates multiple functions such as gene expression and cell death depending on 64 cell types [20,21]. Canonically, three-tiered cascades, MAPK kinase kinase (MAP3K)-MAPK kinase 65 (MAP2K)-MAPK, are the central components of the MAPK pathway, and a tremendous variety of 66 signaling is converged on two exclusive MAPKs, namely, p38s and JNKs [21]. The apoptosis signal- 67regulating kinase (ASK) family, which consists of ASK1, ASK2, and ASK3, is a member of MAP3K and 68 shares similar amino acid sequences throughout the kinase domain but functions differently in many cases 69 [22][23][24]. Additionally, ASKs can form heteromeric complexes and are mutually interactive in some cases 70 [25][26][27][28]. Although the key role of ASK1 is cell death regulation [29][30][31][32][33], we previously reported that ASK1 71 also functions as a differentiation regulator through gene induction in immature brown adipocytes and 72 contributes to functional maturation [9]. However, there have been no reports regarding the functions of 73 the ASK family in mature brown adipocytes. Importantly, cell signaling patterns are incredibly diverse and 74 depend on many parameters,...

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“…The apoptosis signal-regulating kinase (ASK) family, which consists of ASK1, ASK2, and ASK3, is a member of MAP3K and shares similar amino acid sequences throughout the kinase domain but functions differently in many cases [ 22 – 24 ]. Additionally, ASKs can form heteromeric complexes and are mutually interactive in some cases [ 25 – 28 ]. Although the key role of ASK1 is cell death regulation [ 29 – 33 ], we previously reported that ASK1 also functions as a differentiation regulator through gene induction in immature brown adipocytes and contributes to functional maturation [ 9 ].…”

Section: Introductionmentioning

confidence: 99%

β-adrenergic receptor signaling evokes the PKA-ASK axis in mature brown adipocytes

et al. 2020

View full text Add to dashboard Cite

Boosting energy expenditure by harnessing the activity of brown adipocytes is a promising strategy for combatting the global epidemic of obesity. Many studies have revealed that the β 3 -adrenergic receptor agonist is a potent activator of brown adipocytes, even in humans, and PKA and p38 MAPK have been demonstrated for regulating the transcription of a wide range of critical genes such as Ucp1 . We previously revealed that the PKA-ASK1-p38 axis is activated in immature brown adipocytes and contributes to functional maturation. However, the downstream mechanisms of PKA that initiate the p38 MAPK cascade are still mostly unknown in mature brown adipocytes. Here, we identified the ASK family as a crucial signaling molecule bridging PKA and MAPK in mature brown adipocytes. Mechanistically, the phosphorylation of ASK1 at threonine 99 and serine 993 is critical in PKA-dependent ASK1 activation. Additionally, PKA also activates ASK2, which contributes to MAPK regulation. These lines of evidence provide new details for tailoring a βAR-dependent brown adipocyte activation strategy.

show abstract

Structure-based mechanism of preferential complex formation by apoptosis signal–regulating kinases

Cited by 22 publications

References 69 publications

Cells recognize osmotic stress through liquid-liquid phase separation lubricated with poly(ADP-ribose)

Cells recognize osmotic stress through liquid-liquid phase separation lubricated with poly(ADP-ribose)

β-adrenergic receptor signaling evokes the PKA-ASK axis in mature brown adipocytes

β-adrenergic receptor signaling evokes the PKA-ASK axis in mature brown adipocytes

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