Shape transformation of vesicles induced by orientational arrangement of membrane proteins

doi:10.1088/1674-1056/adc36d

中国物理B ›› 2025, Vol. 34 ›› Issue (8): 88706-088706.doi: 10.1088/1674-1056/adc36d

所属专题： SPECIAL TOPIC — A celebration of the 90th Anniversary of the Birth of Bolin Hao

Shape transformation of vesicles induced by orientational arrangement of membrane proteins

Menglong Feng(冯梦龙)^1,†, Kunhao Dong(董堃昊)^1,†, Yuansheng Cao(曹远胜)^2,‡, and Rui Ma(马锐)^3,§

1 Department of Physics, College of Physical Science and Technology, Xiamen University, Xiamen 361005, China;
2 Department of Physics, Tsinghua University, Beijing 100084, China;
3 Fujian Provincial Key Laboratory for Soft Functional Materials Research, Research Institute for Biomimetics and Soft Matter, Department of Physics, College of Physical Science and Technology, Xiamen University, Xiamen 361005, China

收稿日期:2025-03-01 修回日期:2025-03-12 接受日期:2025-03-21 出版日期:2025-07-17 发布日期:2025-07-17
通讯作者: Yuansheng Cao, Rui Ma E-mail:yscao@tsinghua.edu.cn;ruima@xmu.edu.cn
基金资助:
We acknowledge financial support from the the National Natural Science Foundation of China (Grant Nos. 12474199 (RM) and 12374213 (YC)), Fundamental Research Funds for Central Universities of China (Grant No. 20720240144 (RM)), and 111 Project (Grant No. B16029).

Shape transformation of vesicles induced by orientational arrangement of membrane proteins

Menglong Feng(冯梦龙)^1,†, Kunhao Dong(董堃昊)^1,†, Yuansheng Cao(曹远胜)^2,‡, and Rui Ma(马锐)^3,§

1 Department of Physics, College of Physical Science and Technology, Xiamen University, Xiamen 361005, China;
2 Department of Physics, Tsinghua University, Beijing 100084, China;
3 Fujian Provincial Key Laboratory for Soft Functional Materials Research, Research Institute for Biomimetics and Soft Matter, Department of Physics, College of Physical Science and Technology, Xiamen University, Xiamen 361005, China

Received:2025-03-01 Revised:2025-03-12 Accepted:2025-03-21 Online:2025-07-17 Published:2025-07-17
Contact: Yuansheng Cao, Rui Ma E-mail:yscao@tsinghua.edu.cn;ruima@xmu.edu.cn
Supported by:
We acknowledge financial support from the the National Natural Science Foundation of China (Grant Nos. 12474199 (RM) and 12374213 (YC)), Fundamental Research Funds for Central Universities of China (Grant No. 20720240144 (RM)), and 111 Project (Grant No. B16029).

摘要/Abstract

摘要： Vesicles of lipid bilayer can adopt a variety of shapes due to different coating proteins. The ability of proteins to reshape membrane is typically characterized by inducing spontaneous curvature of the membrane at the coated area. BAR family proteins are known to have a crescent shape and can induce membrane curvature along their concaved body axis but not in the perpendicular direction. We model this type of proteins as a rod-shaped molecule with an orientation and induce normal curvature along its orientation in the tangential plane of the membrane surface. We show how a ring of these proteins reshapes an axisymmetric vesicle when the protein curvature or orientation is varied. A discontinuous shape transformation from a protrusion shape without a neck to a one with a neck is found. Increasing the rigidity of the protein ring is able to smooth out the transition. Furthermore, we show that varying the protein orientation is able to induce an hourglass-shaped neck, which is significantly narrower than the reciprocal of the protein curvature. Our results offer a new angle to rationalize the helical structure formed by many proteins that carry out membrane fission functions.

关键词: cell membrane, BAR proteins, anisotropic curvature, shape transformation

Abstract: Vesicles of lipid bilayer can adopt a variety of shapes due to different coating proteins. The ability of proteins to reshape membrane is typically characterized by inducing spontaneous curvature of the membrane at the coated area. BAR family proteins are known to have a crescent shape and can induce membrane curvature along their concaved body axis but not in the perpendicular direction. We model this type of proteins as a rod-shaped molecule with an orientation and induce normal curvature along its orientation in the tangential plane of the membrane surface. We show how a ring of these proteins reshapes an axisymmetric vesicle when the protein curvature or orientation is varied. A discontinuous shape transformation from a protrusion shape without a neck to a one with a neck is found. Increasing the rigidity of the protein ring is able to smooth out the transition. Furthermore, we show that varying the protein orientation is able to induce an hourglass-shaped neck, which is significantly narrower than the reciprocal of the protein curvature. Our results offer a new angle to rationalize the helical structure formed by many proteins that carry out membrane fission functions.

Key words: cell membrane, BAR proteins, anisotropic curvature, shape transformation

中图分类号: (Protein-membrane interactions)

87.15.kt

87.15.K- (Molecular interactions; membrane-protein interactions) 87.17.Rt (Cell adhesion and cell mechanics) 87.10.-e (General theory and mathematical aspects)

Menglong Feng(冯梦龙), Kunhao Dong(董堃昊), Yuansheng Cao(曹远胜), and Rui Ma(马锐). Shape transformation of vesicles induced by orientational arrangement of membrane proteins[J]. 中国物理B, 2025, 34(8): 88706-088706.

Menglong Feng(冯梦龙), Kunhao Dong(董堃昊), Yuansheng Cao(曹远胜), and Rui Ma(马锐). Shape transformation of vesicles induced by orientational arrangement of membrane proteins[J]. Chin. Phys. B, 2025, 34(8): 88706-088706.

参考文献

[1] Decamilli P, Takei K and Mcpherson P 1995 Current Opinion in Neurobiology 5 559
[2] Schmid S, McNiven M and De Camilli P 1998 Current Opinion in Cell Biology 10 504
[3] Turlier H, Audoly B, Prost J and Joanny J F 2014 Biophysical Journal 106 114
[4] Maitre J L, Turlier H, Illukkumbura R, Eismann B, Niwayama R, Nedelec F and Hiiragi T 2016 Nature 536 344
[5] Patra S, Chowdhury D and Juelicher F 2022 Physics Reports 987 1
[6] Antonny B 2006 Current Opinion in Cell Biology 18 386
[7] Zheng B, Meng Q T, Robin Selinger L B, Selinger J V and Ye F F 2015 Chin. Phys. B 24 68701
[8] Schmid S 1997 Annual Review of Biochemistry 66 511
[9] Lichte B, Veh R, Meyer H and Kilimann M 1992 EMBO Journal 11 2521
[10] Sakamuro D, Elliott K, WechslerReya R and Prendergast G 1996 Nature Genetics 14 69
[11] Shimada A, Niwa H, Tsujita K, Suetsugu S, Nitta K, Hanawa-Suetsugu K, Akasaka R, Nishino Y, Toyama M, Chen L, Liu Z J, Wang B C, Yamamoto M, Terada T, Miyazawa A, Tanaka A, Sugano S, Shirouzu M, Nagayama K, Takenawa T and Yokoyama S 2007 Cell 129 761
[12] Takahashi Y, Meyerkord C L and Wang H G 2009 Cell Death and Differentiation 16 947
[13] Laporte D, Coffman V C, Lee I J and Wu J Q 2011 Journal of Cell Biology 192 1005
[14] Zajac A L, Goldman Y E, Holzbaur E L F and Ostap E M 2013 Current Biology 23 1173
[15] McIntosh B B, Pyrpassopoulos S, Holzbaur E L and Ostap E M 2018 Current Biology 28 236
[16] Boulakirba S, Macia E, Partisani M, Lacas-Gervais S, Brau F, Luton F and Franco M 2014 Proc. Natl. Acad. Sci. USA 111 9473
[17] Itoh T, Erdmann K, Roux A, Habermann B, Werner H and De Camilli P 2005 Developmental Cell 9 791
[18] Yang C, Hoelzle M, Disanza A, Scita G and Svitkina T 2009 PLoS One 4 e5678
[19] Hartig S M, Ishikura S, Hicklen R S, Feng Y, Blanchard E G, Voelker K A, Pichot C S, Grange R W, Raphael R M, Klip A and Corey S J 2009 Journal of Cell Science 122 2283
[20] Itoh T, Erdmann K S, Roux A, Habermann B,Werner H and De Camilli P 2005 Developmental Cell 9 791
[21] Neumann S and Schmid S L 2013 Journal of Biological Chemistry 288 25119
[22] Qualmann B, Koch D and Kessels M M 2011 EMBO Journal 30 3501
[23] Farsad K, Ringstad N, Takei K, Floyd S, Rose K and De Camilli P 2001 Journal of Cell Biology 155 193
[24] Gallop J L, Jao C C, Kent H M, Butler P J G, Evans P R, Langen R and T McMahon H 2006 EMBO Journal 25 2898
[25] Mim C, Cui H, Gawronski-Salerno J A, Frost A, Lyman E, Voth G A and Unger V M 2012 Cell 149 137
[26] Li Z L 2018 Chin. Phys. B 27 38703
[27] Frost A, Perera R, Roux A, Spasov K, Destaing O, Egelman E H, De Camilli P and Unger V M 2008 Cell 132 807
[28] Henne W M, Kent H M, Ford M G J, Hegde B G, Daumke O, Butler P J G, Mittal R, Langen R, Evans P R and McMahon H T 2007 Structure 15 839
[29] Saarikangas J, Zhao H, Pykalainen A, Laurinmaki P, Mattila P K, Kinnunen P K J, Butcher S J and Lappalainen P 2009 Current Biology 19 95
[30] Prevost C, Zhao H, Manzi J, Lemichez E, Lappalainen P, Callan-Jones A and Bassereau P 2015 Nat. Commun. 6 8529
[31] Kabaso D, Bobrovska N, Gozdz W, Gov N, Kralj-Iglic V, Veranic P and Iglic A 2012 Journal of Biomechanics 45 231
[32] Ramesh P, Baroji Y F, Reihani S N S, Stamou D, Oddershede L B and Bendix P M 2013 Scientific Reports 3 1565
[33] Simunovic M, Evergren E, Callan-Jones A and Bassereau P 2019 Annual Review of Cell and Developmental Biology 35 111
[34] Zhao H, Pykäläinen A and Lappalainen P 2011 Current Opinion in Cell Biology 23 14
[35] Chen Z, Shi Z and Baumgart T 2015 Biophysical Journal 109 298
[36] Hatzakis N S, Bhatia V K, Larsen J, Madsen K L, Bolinger P Y, Kunding A H, Castillo J, Gether U, Hedegard P and Stamou D 2009 Nature Chemical Biology 5 835
[37] Mesarec L, Góoźdź W, Iglič V K, Kralj S and Iglič A 2016 Colloids and Surfaces B: Biointerfaces 141 132
[38] Noguchi H 2014 Europhys. Lett. 108 48001
[39] Bobrovska N, Gozdz W, Kralj-Iglic V and Iglic A 2013 Plos One 8 e73941
[40] Chan C, Wen H, Lu L and Fan J 2016 Chin. Phys. B 25 18707
[41] Noguchi H 2015 The Journal of Chemical Physics 143 243109
[42] Simunovic M, Srivastava A and Voth G A 2013 Proc. Natl. Acad. Sci. USA 110 20396
[43] Noguchi H, Tozzi C and Arroyo M 2022 Soft Matter 18 3384
[44] Le Roux A L, Tozzi C, Walani N, Quiroga X, Zalvidea D, Trepat X, Staykova M, Arroyo M and Roca-Cusachs P 2021 Nat. Commun. 12 6550
[45] Helfrich W 1973 Zeitschrift für Naturforschung C 28 693
[46] Zhong-can O Y and Helfrich W 1989 Phys. Rev. A 39 5280
[47] Zhan-Chun T 2013 Chin. Phys. B 22 28701
[48] Zhang Y H, McDargh Z and Tu Z C 2018 Chin. Phys. B 27 38704
[49] Kreyszig E 1991 Differential Geometry (New York: Dover)
[50] Zhong Q, Wu C X and Ma R 2023 Chin. Phys. B 32 88704
[51] Perutkova S, Kralj-Iglic V, FrankMand Iglic A 2010 Journal of Biomechanics 43 1612
[52] Mesarec L, Gozdz W, Kralj-Iglic V, Kralj S and Iglic A 2023 Scientific Reports 13 10663
[53] Simunovic M, Evergren E, Golushko I, Prevost C, Renard H F, Johannes L, McMahon H T, Lorman V, Voth G A and Bassereau P 2016 Proc. Natl. Acad. Sci. USA 113 11226
[54] Kralj-Iglic V, Pocsfalvi G, Mesarec L, Sustar V, Hagerstrand H and Iglic A 2020 PLoS One 15 e0244796
[55] Mesarec L, Drab M, Penič S, Kralj-Iglič V and Iglič A 2021 International Journal of Molecular Sciences 22 2348
[56] Kabaso D, Bobrovska N, Góźdź W, Gongadze E, Kralj-Iglič V, Zorec R and Iglič A 2012 Bioelectrochemistry 87 204
[57] Kralj-Iglic V, Heinrich V, Svetina S and Zeks B 1999 Euro. Phys. J. B 10 5
[58] Kralj-Iglic V, Babnik B, Gauger D R, May S and Iglic A 2006 J. Stat. Phys. 125 727
[59] Xiao K, Wu C X and Ma R 2023 Phys. Rev. Res. 5 023176
[60] Onsager L 1949 Annals of the New York Academy of Sciences 51 627
[61] Hinshaw J 2000 Annual Review of Cell and Developmental Biology 16 483
[62] Sweitzer S and Hinshaw J 1998 Cell 93 1021
[63] Meinecke M, Boucrot E, Camdere G, Hon W C, Mittal R and McMahon H T 2013 Journal of Biological Chemistry 288 6651
[64] Kukulski W, Schorb M, Kaksonen M and Briggs J A G 2012 Cell 150 508
[65] Kishimoto T, Sun Y, Buser C, Liu J, Michelot A and Drubin D G 2011 Proc. Natl. Acad. Sci. USA 108 E979
[66] Hohendahl A, Talledge N, Galli V, Shen P S, Humbert F, De Camilli P, Frost A and Roux A 2017 eLife 6 e26856
[67] Agrawal A and Steigmann D J 2009 Biomechanics and Modeling in Mechanobiology 8 371

Shape transformation of vesicles induced by orientational arrangement of membrane proteins

Shape transformation of vesicles induced by orientational arrangement of membrane proteins

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