Plant Molecular Farming Using Oleosin Partitioning Technology in Oilseeds

  • Moloney, Maurice-M. (Department of Biological Science, University of Calgary)
  • 발행 : 1997.07.01

초록

Plant seed oil-bodies or oleosomes ate the repository of the neutral lipid stored in seeds. These organelles in many oilseeds may comprise half of the total cellular volume. Oleosomes are surrounded by a half-unit membrane of phospholipid into which are embedded proteins called oleosins. Oleosins are present at high density on the oil-body surface and after storage proteins comprise the most abundant proteins in oilseeds. Oleosins are specifically targeted and anchored to oil-bodies after co-translation on the ER. It has been shown that the amino-acid sequences responsible for this unique targeting reside primarily in the central hydrophobic tore of the oleosin polypeptide. In addition, a signal-like sequence is found near the junction of the hydrophobic domain and ann N-terminal hydrophilic / amphipathic domain. This "signal" which is uncleaved is also essential for correct targeting. Oil-bodies and their associated oleosins may be recovered by floatation centrifugation of aqueous seed extracts. This simple partitioning step results in a dramatic enrichment for oleosins in the oil-body fraction. In the light of these properties, we reasoned that it would be feasible to create fusion proteins on oil-bodies comprising oleosins and an additional valuable protein of pharmaceutical or industrial interest. It was further postulated that if these proteins were displayed on the outer surface of oil-bodies, it would be possible to release them from the purified oil-bodies using chemical or proteolytic cleavage. This could result in a simple means of recovering high-value protein from seeds at a significant (i.e. commercial) scale. This procedure has been successfully reduced to practice for a wide variety of proteins of therapeutic, industrial and food no. The utillity of the method will be discussed using a blood anticoagulant, hirudin, and industrial enzymes as key examples.

키워드

참고문헌

  1. Eur J Biochem v.226 C-terminal proteolytic degradation of recombinant desulfato-hirudin and its mutants in the yeast Saccharomyces cerevisiae Heim J;Takabayashi K;Meyhack B;Marki W;Pohlig G
  2. Planta v.189 Targeting of oleosins to oil bodies of oilseed rape(Brassica napus L.) Hils MJ;Watson MD;Murphy DJ
  3. Plant Mol Biol v.11 A modified storage protein is synthesized, processed and degraded in the seeds of transgenic plants Hoffman LM;Donaldson DD;Herman EM
  4. Plant Physiol v.110 Oleosins and oil bodies in seeds and other organs Huang AHC
  5. J. Bacteriol v.174 Role of the two-component leader sequence and mature amino acid sequences in extracellular export of endoglucanase EGL from Pseudomonas solanacearum Huang J;Schell MA
  6. Plant Cell v.1 Endoplasmic reticulumtargeting and glycosylation of hybrid proteins in transgenic tabacco Iturriage G;Jefferson RA;Bevan MW
  7. JAOCS v.67 Isolation and physiocochemical characterization of the half-unit membranes of oilseed lipid bodies Jacks TJ;Hensarling TP;Neucere JN;Yatsu LY;Barker RH
  8. TIBTECH v.8 production of peptides in plant seeds Krebbers E;Vandekerckhove J
  9. JAOCS v.73 Oil bodies of transgenic Brassica napus as a source of immobilized β-glucuronidase Kuhnel B;Holbrook LA;Moloney MM;Van Rooijen GJH
  10. Plant Physiol v.101 Cotranslational integration of soybean(Glycine max)oil body membrane protein oleosin into microsomal membranes Loer D;Herman EM
  11. INFORM v.7 Recombinant proteins via oleosin partitioning Moloney MM;Van Rooijen GJH
  12. Plant Cell Report v.8 High efficiency transformation of Brassica napus using Agrobacterium vectors Moloney MM;Walker JM;Sharma KK
  13. Plant Physiol v.109 Structural requirements of oleosin domains for subcellular targetig to the oil body Van Rooijen GJH;Moloney MM
  14. Bio/Tech v.13 Plant seed oil-bodies as carriers for foreign proteins Van Rooijen GJH;Moloney MM