COMMENTARY ON THE LAW

Plant storage proteins – the main nourisching products – from biosynthesis to cellular storage depots

Agnieszka Chmielnicka¹ , Aneta Żabka¹ , Konrad Winnicki¹ , Justyna Teresa Polit¹

1. Katedra Cytofizjologii, Wydział Biologii i Ochrony Środowiska, Uniwersytet Łódzki

Published: 2017-06-19

DOI: 10.5604/01.3001.0010.3834

GICID: 01.3001.0010.3834

Available language versions: en pl

Issue: Postepy Hig Med Dosw 2017; 71 : 530-540

Abstract

Storage proteins of legumes are one of the main components of the human and animal diet. The substances collected in their seeds have the pro-health values, supporting the prevention of many civilization diseases. However, there are still many uncertainties about the mechanisms leading to the production of nutritious seeds. It is also difficult to identify which of their constituents and in what final form are responsible for the observed protective effects in vivo. In this work, on the background of different types of storage proteins, these deposited mainly in legumes were in the focus of interest. They were characterized on the example of pea (Pisum sativum) proteins. Mechanisms associated with their biosynthesis and transport to specific cellular compartments was presented. Ways of their post-translational processing, segregation and storage in the specific vacuoles were also discussed. Therefore, the paper presents the state-of-the-art knowledge concerning the processes making the accumulated protein deposits ready to use by plants, animals and humans.

References

1. Abirached-Darmency M., Dessaint F., Benlicha E., Schneider C.: Biogenesis of protein bodies during vicilin accumulation in Medicago truncatula immature seeds. BMC Res. Notes, 2012; 5: 409
Google Scholar
2. Ali M.H., Imperiali B.: Protein oligomerization: how and why. Bioorg. Med. Chem., 2005; 13: 5013-5020
Google Scholar
3. Anderson T.J., Lamsal B.P.: Zein extraction from corn, corn products, and coproducts and modifications for various applications: a review. Cereal Chem., 2011; 88: 159-173
Google Scholar
4. Barac M., Cabrilo S., Pesic M., Stanojevic S., Zilic S., Macej O., Ristic N.: Profile and functional properties of seed proteins from six pea (Pisum sativum) genotypes. Int. J. Mol. Sci., 2010; 11: 4973-4990
Google Scholar
5. Basińska A., Krzesłowska M., Woźny A.: Nowe fakty dotyczą- ce transportu pęcherzykowego w komórkach roślinnych. Kosmos, 2012; 61: 363-370
Google Scholar
6. Casey R., Christou P., Domoney C., Hedley C., Hitchin E., Parker M., Stoger E., Wang T., Zasiura C.: Expression of legumin and vicilin genes in pea mutants and the production of legumin in transgenic plants. Nahrung, 2001; 45: 385-387
Google Scholar
7. Clemente A., Marín-Manzano M.C., Jiménez E., Arqués M.C., Domoney C.: The anti-proliferative effect of TI1B, a major BowmanBirk isoinhibitor from pea (Pisum sativum L.), on HT29 colon cancer cells is mediated through protease inhibition. Br. J. Nutr., 2012; 108 (Suppl. 1): S135-S144
Google Scholar
8. Czarnecka J., Koziołkiewicz M.: Albuminy 2S – roślinne białka zapasowe o właściwościach alergennych. Biotechnologia, 2007; 2: 114-127
Google Scholar
9. De Marchis F., Bellucci M., Pompa A.: Unconventional pathways of secretory plant proteins from the endoplasmic reticulum to the vacuole bypassing the Golgi complex. Plant Signal. Behav., 2013; 8: e25129
Google Scholar
10. Duranti M.: Grain legume proteins and nutraceutical properties. Fitoterapia, 2006; 77: 67-82
Google Scholar
11. Ebine K., Okatani Y., Uemura T., Goh T., Shoda K., Niihama M., Morita M.T., Spitzer C., Otegui M.S., Nakano A., Ueda T.: A SNARE complex unique to seed plants is required for protein storage vacuole biogenesis and seed development of Arabidopsis thaliana. Plant Cell, 2008; 20: 3006-3021
Google Scholar
12. Ebine K., Ueda T.: Unique mechanism of plant endocytic/vacuolar transport pathways. J. Plant Res., 2009; 122: 21-30
Google Scholar
13. Egea P.F., Stroud R.M., Walter P.: Targeting proteins to membranes: structure of the signal recognition particle. Curr. Opin. Struct. Biol., 2005; 15: 213-220
Google Scholar
14. Faso C., Boulaflous A., Brandizzi F.: The plant Golgi apparatus: last 10 years of answered and open questions. FEBS Lett., 2009; 583: 3752-3757
Google Scholar
15. Feeney M., Frigerio L., Kohalmi S.E., Cui Y., Menassa R.: Reprogramming cells to study vacuolar development. Front. Plant Sci., 2013; 4: 493
Google Scholar
16. Freitas R.L., Teixeira A.R., Ferreira R.B.: Vicilin-type globulins follow distinct patterns of degradation in different species of germinating legume seeds. Food Chem., 2007; 102: 323-329
Google Scholar
17. Frigerio L., Hinz G., Robinson D.G.: Multiple vacuoles in plant cells: rule or exception? Traffic, 2008; 9: 1564-1570
Google Scholar
18. Galili G.: ER-derived compartments are formed by highly regulated processes and have special functions in plants. Plant Physiol., 2004; 136: 3411-3413
Google Scholar
19. Gallardo K., Thompson R., Burstin J.: Reserve accumulation in legume seeds. C.R. Biol., 2008; 331: 755-762
Google Scholar
20. Gatehouse J.A., Croy R.R., Morton H., Tyler M., Boulter D.: Characterisation and subunit structures of the vicilin storage proteins of pea (Pisum sativum L.). Eur. J. Biochem., 1981; 118: 627-633
Google Scholar
21. Gatehouse J.A., Evans I.M., Bown D., Croy R.R., Boulter D.: Control of storage-protein synthesis during seed development in pea (Pisum sativum L.). Biochem. J., 1982; 208: 119-127
Google Scholar
22. Gattolin S., Sorieul M., Hunter P.R., Khonsari R.H., FrigerioL.: In vivo imaging of the tonoplast intrinsic protein family in Arabidopsis roots. BMC Plant Biol., 2009; 9: 133
Google Scholar
23. Hanton S.L., Matheson L.A., Brandizzi F.: Seeking a way out: export of proteins from the plant endoplasmic reticulum. Trends Plant Sci., 2006; 11: 335-343
Google Scholar
24. Herman E.M., Larkins B.A.: Protein storage bodies and vacuoles. Plant Cell, 1999; 11: 601-613
Google Scholar
25. Hillmer S., Movafeghi A., Robinson D.G., Hinz G.: Vacuolar storage proteins are sorted in the cis-cisternae of the pea cotyledon Golgi apparatus. J. Cell Biol., 2001; 152: 41-50
Google Scholar
26. Hiss J.A., Schneider G.: Architecture, function and prediction of long signal peptides. Brief. Bioinform., 2009; 10: 569-578
Google Scholar
27. Hohl I., Robinson D.G., Chrispeels M.J., Hinz G.: Transport of storage proteins to the vacuole is mediated by vesicles without a clathrin coat. J. Cell Sci., 1996; 109: 2539-2550
Google Scholar
28. Holding D.R., Larkins B.A.: The development and importance of zein protein bodies in maize endosperm. Maydica, 2006; 51: 243-254
Google Scholar
29. Isayenkov S., Isner J.C., Maathuis F.J.: Vacuolar ion channels: Roles in plant nutrition and signalling. FEBS Lett., 2010; 584: 1982- 1988
Google Scholar
30. Leterme P.: Recommendations by health organizations for pulse consumption. Br. J. Nutr., 2002; 88 (Suppl. 3): S239-S242
Google Scholar
31. Marti L., Fornaciari S., Renna L., Stefano G., Brandizzi F.: COPIImediated traffic in plants. Trends Plant Sci., 2010; 15: 522-528
Google Scholar
32. Martínez-Villaluenga C., Gulewicz P., Frias J., Gulewicz K., Vidal-Valverde C.: Assessment of protein fractions of three cultivars of Pisum sativum L.: Effect of germination. Eur. Food Res. Technol., 2008; 226:1465-1478
Google Scholar
33. Maruyama N., Mun L.C., Tatsuhara M., Sawada M., Ishimoto M., Utsumi S.: Multiple vacuolar sorting determinants exist in soybean 11S globulin. Plant Cell, 2006; 18: 1253-1273
Google Scholar
34. Masclaux F.G., Galaud J.P., Pont-Lezica R.: The riddle of the plant vacuolar sorting receptors. Protoplasma, 2005; 226: 103-108
Google Scholar
35. Mertens C., Dehon L., Bourgeois A., Verhaeghe-Cartrysse C., Blecker C.: Agronomical factors influencing the legumin/vicilin ratio in pea (Pisum sativum L.) seeds. J. Sci. Food Agric., 2012; 92: 1591-1596
Google Scholar
36. Meusser B., Hirsch C., Jarosch E., Sommer T.: ERAD: the long road to destruction. Nat. Cell Biol., 2005; 7: 766-772
Google Scholar
37. Mori T., Saruta Y., Fukuda T., Prak K., Ishimoto M., Maruyama N., Utsumi S.: Vacuolar sorting behaviors of 11S globulins in plant cells. Biosci., Biotechnol. Biochem., 2009; 73: 53-60
Google Scholar
38. Müntz K.: Deposition of storage proteins. Plant Mol. Biol., 1998; 38: 77-99
Google Scholar
39. Müntz K.: Protein dynamics and proteolysis in plant vacuoles. J. Exp. Bot., 2007; 580: 2391-2407
Google Scholar
40. Nielsen H., Krogh A.: Prediction of signal peptides and signal anchors by a hidden Markov model. Proc. Int. Conf. Intell. Syst. Mol. Biol., 1998; 6: 122-130
Google Scholar
41. O’kane F.E., Happe R. P., Vereijken J. M., Gruppen H., van Boekel M.A.: Characterization of pea vicilin. 1. Denoting convicilin as the α-subunit of the Pisum vicilin family. J. Agric. Food Chem., 2004; 52: 3141-3148
Google Scholar
42. Olbrich A., Hillmer S., Hinz G., Oliviusson P., Robinson D.G.: Newly formed vacuoles in root meristems of barley and pea seedlings have characteristics of both protein storage and lytic vacuoles. Plant Physiol., 2007; 145: 1383-1394
Google Scholar
43. Onda Y.: Oxidative protein-folding systems in plant cells. Int. J. Cell Biol., 2013; 2013: 585431
Google Scholar
44. Park M., Kim S.J., Vitale A., Hwang I.: Identification of the protein storage vacuole and protein targeting to the vacuole in leaf cells of three plant species. Plant Physiol., 2004; 134: 625-639
Google Scholar
45. Pedrosa C., De Felice F.G., Trisciuzzi C., Ferreira S.T.: Selective neoglycosylation increases the structural stability of vicilin, the 7S storage globulin from pea seeds. Arch. Biochem. Biophys., 2000; 382: 203-210
Google Scholar
46. Pereira C., Pereira S., Pissarra J.: Delivering of proteins to the plant vacuole – an update. Int. J. Mol. Sci., 2014; 15: 7611-7623
Google Scholar
47. Pimpl P., Taylor J.P., Snowden C., Hillmer S., Robinson D.G., Denecke J.: Golgi-mediated vacuolar sorting of the endoplasmic reticulum chaperone BiP may play an active role in quality control within the secretory pathway. Plant Cell, 2006; 18: 198-211
Google Scholar
48. Pool M.R., Stumm J., Fulga T.A., Sinning I., Dobberstein B.: Distinct modes of signal recognition particle interaction with the ribosome. Science, 2002; 297: 1345-1348
Google Scholar
49. Popoff V., Adolf F., Brügger B., Wieland F.: COPI budding within the Golgi stack. Cold Spring Harb. Perspect. Biol., 2011; 3: a005231
Google Scholar
50. Prandini A., Sigolo S., Morlacchini M., Cerioli C., Masoero F.: Pea (Pisum sativum) and faba bean (Vicia faba L.) seeds as protein sources in growing-finishing heavy pig diets: effect on growth performance, carcass characteristics and on fresh and seasoned Parma ham quality. Ital. J. Anim. Sci., 2011; 10: e45
Google Scholar
51. Raghavan V.: Molecular embryology of flowering plants. Cambridge University Press, 1997
Google Scholar
52. Robinson D.G., Oliviusson P., Hinz G.: Protein sorting to the storage vacuoles of plants: a critical appraisal. Traffic, 2005; 6: 615-625
Google Scholar
53. Rubio L.A., Pérez A., Ruiz R., Guzmán M.Á., Aranda-Olmedo A., Clemente A.: Characterization of pea (Pisum sativum) seed protein fractions. J. Sci. Food Agric., 2014; 94: 280-287
Google Scholar
54. Shewry P.R., Napier J.A., Tatham A.S.: Seed storage proteins: structures and biosynthesis. Plant Cell, 1995; 7: 945-956
Google Scholar
55. Strating J.R., Martens G.J.: The p24 family and selective transport processes at the ER-Golgi interface. Biol. Cell, 2009; 101: 495-509
Google Scholar
56. Tosi P., Parker M., Gritsch C.S., Carzaniga R., Martin B., Shewry P.R.: Trafficking of storage proteins in developing grain of wheat. J. Exp. Bot., 2009; 60: 979-991
Google Scholar
57. Törmäkangas K., Hadlington J.L., Pimpl P., Hillmer S., Brandizzi F., Teeri T.H., Denecke J.: A vacuolar sorting domain may also influence the way in which proteins leave the endoplasmic reticulum. Plant Cell, 2001; 13: 2021-2032
Google Scholar
58. Tzitzikas E.N., Vincken J.P., de Groot J., Gruppen H., Visser R.G.: Genetic variation in pea seed globulin composition. J. Agric. Food Chem., 2006; 54: 425-433
Google Scholar
59. Viotti C.: ER and vacuoles: never been closer. Front. Plant Sci., 2014; 5: 20
Google Scholar
60. von Lüpke A., Schauermann G., Feussner I., Hinz G.: Peripheral membrane proteins mediate binding of vacuolar storage proteins to membranes of the secretory pathway of developing pea cotyledons. J. Exp. Bot., 2008; 59: 1327-1340
Google Scholar
61. Wang H., Rogers J.C., Jiang L.: Plant RMR proteins: unique vacuolar sorting receptors that couple ligand sorting with membrane internalization. FEBS J., 2011; 278: 59-68
Google Scholar
62. Woźny A., Jackowski G., Jarmuszkiewicz W., Ratajczak L., Szweykowska-Kulińska Z.: Sortowanie i transport białek. W: Biologia komórki roślinnej, t. 2, red.: P. Wojtaszek, A. Woźny, L. Ratajczak. Wydawnictwo Naukowe PWN SA, Warszawa 2007
Google Scholar
63. Xiang L., Etxeberria E., Van den Ende W.: Vacuolar protein sorting mechanisms in plants. FEBS J., 2013; 280: 979-993
Google Scholar
64. Zheng H., Staehelin L.A.: Protein storage vacuoles are transformed into lytic vacuoles in root meristematic cells of germinating seedlings by multiple, cell type-specific mechanisms. Plant Physiol., 2011; 155: 2023-2035
Google Scholar

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