References

Berger S, Bell E, Sadka V, Mullet JE (1995) Arabidopsis thaliana Atvsp is homologous to soybean VspA and VspB, genes encoding vegetative storage protein acid phosphatases and is regulated similarly by methyl jasmonate, wounding, sugar light and phosphate. Plant Molecular Biology 27, 933–942.
| CrossRef | CAS |

Bradford MM (1976) A rapid and sensitive method for the quantitation of microgram quantities of protein utilising the principle of protein-dye binding. Analytical Biochemistry 72, 248–254.
| CrossRef | CAS |

Brock TG, McNish RW, Bailie MB, Peters-Golden M (1997) Rapid Import of cytosolic 5-lipoxygenase into the nucleus of neutrophils after in vivo recruitment and in vitro adherence. Journal of Biological Chemistry 272, 8276–8280.
| CrossRef | CAS |

Brock TG, Anderson JA, Fries FP, Peters-Golden M, Sporn PHS (1999) Decreased leukotriene C₄ synthesis accompanies adherence-dependent nuclear import of 5-lipoxygenase in human blood eosinophils. Journal of Immunology 162, 1669–1676.
| CAS |

Brubaker CL, Lersten NR (1995) Paraveinal mesophyll: review and survey of the subtribe Erythrinae (Phaseolae, Papilionoideae, Leguminosae). Plant Systematics and Evolution 196, 31–62.
| CrossRef |

Bunker TW, Koetje DS, Stephenson LC, Creelman RA, Mullet JE, Grimes HD (1995) Sink limitation induces the expression of multiple soybean vegetative lipoxygenase mRNAs while the endogenous jasmonic acid level remains low. The Plant Cell 7, 1319–1331.
| CAS |

DeWald DB, Mason HS, Mullet JE (1992) The soybean vegetative storage proteins VSPα and VSPβ are acid phosphatases active on phosphates. Journal of Biological Chemistry 267, 15958–15964.
| CAS |

Dubbs WE, Grimes HD (2000) The mid-pericarp cell layer in soybean pod walls is a multicellular compartment enriched in specific lipoxygenase isoforms. Plant Physiology 123, 1281–1288.
| CrossRef | CAS |

Felton GW (2005) Indigestion in a plant’s best defense. Proceedings of the National Academy of Sciences of the United States of America 102, 18771–18772.
| CrossRef | CAS |

Felton GW, Bi JL, Summers CB, Mueller AJ, Duffy SS (1994) Potential role of lipoxygenases in defense against insect herbivory. Journal of Chemical Ecology 20, 651–666.
| CrossRef | CAS |

Fischer AM, Dubbs WE, Baker RA, Fuller MA, Stephenson LC, Grimes HD (1999) Protein dynamics, activity and cellular localisation of soybean lipoxygenases indicate distinct functional roles for individual isoforms. The Plant Journal 19, 543–554.
| CrossRef | CAS |

Fisher DB (1967) An unusual layer of cells in the mesophyll of the soybean leaf. Botanical Gazette (Chicago, Ill.) 128, 215–218.
| CrossRef |

Franceschi VR, Giaquinta RT (1983a) Specialised cellular arrangements in legume leaves in relation to assimilate transport and compartmentation. Comparison of the paraveinal mesophyll. Planta 159, 415–422.
| CrossRef |

Franceschi VR, Giaquinta RT (1983b) The paraveinal mesophyll of soybean leaves in relation to assimilate transfer and compartmentation. Ultrastructure and histochemistry during vegetative development. Planta 157, 422–431.
| CrossRef | CAS |

Franceschi VR, Grimes HD (1991) Induction of soybean vegetative storage proteins and anthocyanins by low-level atmospheric methyl jasmonate. Proceedings of the National Academy of Sciences of the United States of America 88, 6745–6749.
| CrossRef | CAS |

Franceschi VR, Wittenbach VA, Giaquinta RT (1983) Paraveinal mesophyll of soybean leaves in relation to assimilate transfer and compartmentation. Plant Physiology 72, 586–589.
| CrossRef | CAS |

Franceschi VR, Ding B, Lucas WJ (1994) Mechanism of plasmodesmata formation in characean algae in relation to evolution of intercellular commnunication in higher plants. Planta 192, 347–358.
| CrossRef |

Fuller MA, Weichert H, Fischer AM, Feussner I, Grimes HD (2001) Activity of soybean lipoxygenase isoforms against esterified fatty acids indicates functional specificity. Archives of Biochemistry and Biophysics 388, 146–154.
| CrossRef | CAS |

Grayburn SW, Schneider GR, Hamilton-Kemp TR, Bookjans G, Ali K, Hildebrand DF (1991) Soybean leaves contain multiple lipoxygenases. Plant Physiology 95, 1214–1218.
| CrossRef | CAS |

Hanaka H, Shimizu T, Izumi T (2002) Nuclear-localisation-signal-dependent and nuclear-export-signal-dependent mechanisms determine the localisation of 5-lipoxygenase. Biochemical Journal 361, 505–514.
| CrossRef | CAS |

Howe GA, Jander G (2008) Plant immunity to insect herbivores. Annual Review of Plant Biology 59, 41–66.
| CrossRef | CAS |

Kato T, Shirano Y, Iwamoto H, Shibata D (1993) Soybean lipoxygenase L-4, a component of the 94-kilodalton storage protein in vegetative tissues: expression and accumulation in leaves induced by pod removal and by methyl jasmonate. Plant & Cell Physiology 34, 1063–1072.
| CAS |

Klauer SF, Franceschi VR (1997) Mechanism of transport of vegetative storage proteins to the vacuole of the paraveinal mesophyll. Protoplasma 200, 174–185.
| CrossRef | CAS |

Leelapon O, Sarath G, Staswick PE (2004) A single amino acid substitution in soybean VSPα increases its acid phosphatase activity nearly 20 fold. Planta 219, 1071–1079.
| CrossRef | CAS |

Murphy KA, Kuhle RA, Fischer AM, Anterola AM, Grimes HD (2005) The functional status of paraveinal mesophyll vacuoles changes in response to altered metabolic conditions in soybean leaves. Functional Plant Biology 32, 335–344.
| CrossRef | CAS |

Nakai K, Horton P (1999) PSORT: a program for detecting sorting signals in proteins and predicting their subcellular localisation. Trends in Biochemical Sciences 24, 34–35.
| CrossRef | CAS |

Porta H, Rocha-Sosa M (2002) Plant lipoxygenases. Physiological and molecular features. Plant Physiology 130, 15–21.
| CrossRef | CAS |

Sellhorn GE, Youn B, Webb BN, Gloss LM, Kang C, Grimes H (2011) Biochemical characterisation, kinetic analysis and molecular modeling of recombinant vegetative lipoxygenases from soybean. International Journal of Biology 3, 44–62.
| CAS |

Staswick PE (1988) Soybean vegetative storage protein structure and gene expression. Plant Physiology 87, 250–254.
| CrossRef | CAS |

Staswick PE (1989) Developmental regulation and the influence of plant sinks on vegetative storage protein gene expression in soybean leaves. Plant Physiology 89, 309–315.
| CrossRef | CAS |

Staswick PE (1994) Storage proteins of vegetative plant tissues. Annual Review of Plant Physiology and Plant Molecular Biology 45, 303–322.
| CrossRef | CAS |

Stephenson LC, Bunker TW, Dubbs WE, Grimes HD (1998) Specific soybean lipoxygenases localise to discrete subcellular compartments and their mRNAs are differentially regulated by source-sink status. Plant Physiology 116, 923–933.
| CrossRef | CAS |

Tranbarger TJ, Franceschi VR, Hildebrand DF, Grimes HD (1991) The soybean 94-kilodalton vegetative storage protein is a lipoxygenase that is localised in paraveinal mesophyll cell vacuoles. The Plant Cell 3, 973–987.
| CAS |

Wittenbach VA (1982) Effect of pod removal on leaf senescence in soybeans. Plant Physiology 70, 1544–1548.
| CrossRef | CAS |

Wittenbach VA (1983a) Effect of pod removal on leaf photosynthesis and soluble protein composition of field-grown soybeans. Plant Physiology 73, 121–124.
| CrossRef | CAS |

Wittenbach VA (1983b) Purification and characterisation of a soybean leaf storage glycoprotein. Plant Physiology 73, 125–129.
| CrossRef | CAS |

Youn B, Sellhorn GE, Mirchel RJ, Gaffney BJ, Grimes HD, Kang C (2006) Crystal structures of vegetative soybean lipoxygenase VLX-B and VLX-D and comparisons with seed isoforms LOX-1 and LOX-3. Proteins 65, 1008–1020.
| CrossRef | CAS |

Zhu-Salzman K, Luthe DS, Felton GW (2008) Arthropod-inducible proteins: broad spectrum defenses against multiple herbivores. Plant Physiology 146, 852–858.
| CrossRef | CAS |