Physcomitrella patens      Scaffold


※ Scaffold introduction

    Scaffolds were defined as the drivers of LLPS essential for the structural integrity of MLOs, and the major components which, alone or with co-scaffolds, undergo LLPS (1-4). A minimum set of six experimental tests, including the assembly of spherical droplets, the observation of fusion events, and the identification of mutations that abolish or inhibit LLPS in vitro and in cells have been proposed for rigorous analysis of LLPS processes (1). For each known scaffold protein, descriptions on performed assays of the minimum set of experiments were presented on its gene page. For example, the human fused in sarcoma (FUS), a well-characterized RNA-binding protein undergoing LLPS involved in formation of multiple biomolecular condensates (5,6-8), forms liquid-like droplets both in cells and at near physiological conditions in vitro. All the six experimental tests were performed to analyze the LLPS properties of FUS (9).

References
1. Alberti, S., Gladfelter, A. and Mittag, T. (2019) Considerations and challenges in studying liquid-liquid phase separation and biomolecular condensates. Cell, 176, 419-434. PMID: 30682370
2. Banani, S.F., Lee, H.O., Hyman, A.A. and Rosen, M.K. (2017) Biomolecular condensates: organizers of cellular biochemistry. Nat. Rev. Mol. Cell Biol. 18, 285-298. PMID: 28225081
3. Banani, S.F., Rice, A.M., Peeples, W.B., Lin, Y., Jain, S., Parker, R. and Rosen, M.K. (2016) Compositional control of phase-separated cellular bodies. Cell, 166, 651-663. PMID: 27374333
4. Hyman, A.A. and Simons, K. (2012) Cell biology. Beyond oil and water--phase transitions in cells. Science, 337, 1047-1049. PMID: 22936764
5. Hofweber, M., Hutten, S., Bourgeois, B., Spreitzer, E., Niedner-Boblenz, A., Schifferer, M., Ruepp, M.D., Simons, M., Niessing, D., Madl, T. et al. (2018) Phase Separation of FUS Is Suppressed by Its Nuclear Import Receptor and Arginine Methylation. Cell, 173, 706-719 e713. PMID: 29677514
6. Murray, D.T., Kato, M., Lin, Y., Thurber, K.R., Hung, I., McKnight, S.L. and Tycko, R. (2017) Structure of FUS Protein Fibrils and Its Relevance to Self-Assembly and Phase Separation of Low-Complexity Domains. Cell, 171, 615-627 e61. PMID: 28942918
7. Guo, L., Kim, H.J., Wang, H., Monaghan, J., Freyermuth, F., Sung, J.C., O'Donovan, K., Fare, C.M., Diaz, Z., Singh, N. et al. (2018) Nuclear-Import Receptors Reverse Aberrant Phase Transitions of RNA-Binding Proteins with Prion-like Domains. Cell, 173, 677-692 e20. PMID: 29677512
8. Yoshizawa, T., Ali, R., Jiou, J., Fung, H.Y.J., Burke, K.A., Kim, S.J., Lin, Y., Peeples, W.B., Saltzberg, D., Soniat, M. et al. (2018) Nuclear Import Receptor Inhibits Phase Separation of FUS through Binding to Multiple Sites. Cell, 173, 693-705 e22. PMID: 29677513
9. Patel, A., Lee, H.O., Jawerth, L., Maharana, S., Jahnel, M., Hein, M.Y., Stoynov, S., Mahamid, J., Saha, S., Franzmann, T.M. et al. (2015) A Liquid-to-Solid Phase Transition of the ALS Protein FUS Accelerated by Disease Mutation. Cell, 57, 162, 1066-1077. PMID: 26317470


There are 35 genes.  Reviewed (0 or Unreviewed (35

No.StatusDrLLPS IDEnsemble Gene IDUniProt AccessionGene Name
1
LLPS-Php-1664
Pp3c14_11180
A0A2K1JHB2
LSM4
2
LLPS-Php-0091
Pp3c1_3230
A0A2K1L6Q0
PHYPA_000130
3
LLPS-Php-1478
Pp3c1_7160
A9S013
PHYPA_000312
4
LLPS-Php-0297
Pp3c1_31280
A0A2K1LAF6
PHYPA_001431
5
LLPS-Php-2515
Pp3c2_4060
A0A2K1L046
PHYPA_002182
6
LLPS-Php-0383
Pp3c2_9140
A0A2K1L0S1
PHYPA_002416
7
LLPS-Php-1785
Pp3c2_9144
A0A2K1L0T5
PHYPA_002417
8
LLPS-Php-1936
Pp3c2_16780
A0A2K1L1U4
PHYPA_002792
9
LLPS-Php-1263
Pp3c2_16830
A0A2K1L1U6
PHYPA_002796
10
LLPS-Php-1165
Pp3c3_14480
A0A2K1KUG1
PHYPA_004423
11
LLPS-Php-0217
Pp3c3_17910
A0A2K1KUY3
PHYPA_004591
12
LLPS-Php-1077
Pp3c3_36480
A0A2K1KXI0
PHYPA_005464
13
LLPS-Php-1358
Pp3c5_28430
A0A2K1KLD0
PHYPA_008256
14
LLPS-Php-1590
Pp3c8_6680
A0A2K1K6D7
PHYPA_011239
15
LLPS-Php-2454
Pp3c9_1000
A0A2K1K1G8
PHYPA_012097
16
LLPS-Php-0873
Pp3c10_4970
A0A2K1JXS5
PHYPA_013446
17
LLPS-Php-0265
Pp3c10_5440
A9S636
PHYPA_013465
18
LLPS-Php-0153
Pp3c11_24660
A0A2K1JW55
PHYPA_015531
19
LLPS-Php-0082
Pp3c11_26710
A9TV49
PHYPA_015633
20
LLPS-Php-1878
Pp3c12_23420
A0A2K1JRW9
PHYPA_016661
21
LLPS-Php-1526
Pp3c13_15920
A9U378
PHYPA_017452
22
LLPS-Php-1207
Pp3c14_13370
A0A2K1JHR4
PHYPA_018462
23
LLPS-Php-1468
Pp3c14_14540
A0A2K1JHT7
PHYPA_018521
24
LLPS-Php-0309
Pp3c15_14630
A0A2K1JD76
PHYPA_019755
25
LLPS-Php-0296
Pp3c17_1620
A9T0V1
PHYPA_021545
26
LLPS-Php-0773
Pp3c17_16170
A0A2K1J449
PHYPA_022160
27
LLPS-Php-1175
Pp3c17_17420
A0A2K1J4C5
PHYPA_022227
28
LLPS-Php-0707
Pp3c19_17160
A0A2K1IYR3
PHYPA_024240
29
LLPS-Php-0809
Pp3c24_17510
A0A2K1IH61
PHYPA_029210
30
LLPS-Php-1723
Pp3c25_990
A9TEQ9
PHYPA_029428
31
LLPS-Php-0446
Pp3c26_7720
A0A2K1IC71
PHYPA_030364
32
LLPS-Php-0867
Pp3c27_1630
A0A2K1IA77
PHYPA_030757
33
LLPS-Php-1514
Pp3c27_2160
A0A2K1IAA5
PHYPA_030786
34
LLPS-Php-2173
Pp3c27_4160
A0A2K1IAM7
PHYPA_030901
35
LLPS-Php-0414
Pp3s121_40
A0A2K1I9Y6
PHYPA_031142