The production of long chain polyunsaturated fatty acids in transgenic plants by reverse-engineering

The nutritional importance of long chain polyunsaturated fatty acids (LC-PUFAs) is now well-established, with these lipids playing roles in human development and the prevention of various diseases. In particular, n-3 polyunsaturated fatty acids are protective against cardiovascular disease (CVD) and risks associated with metabolic syndrome. In view of the decline in marine fish stocks, which represent the predominant natural reserves of n-3 long chain polyunsaturates, alternative sources are urgently required. One approach may be to express the LC-PUFA-biosynthetic pathway in transgenic plants. Recent progress in validating this approach has now emerged, demonstrating the feasibility of using transgenic plants to synthesise these important human nutrients.     

Targeting and membrane-insertion of a sunflower oleosin in vitro and in <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>: the central hydrophobic domain contains more than one signal sequence,and directs oleosin insertion into the endoplasmic reticulum membrane using a signal anchor sequence mechanism

A range of N- and C-terminal deletions of an oleosin from Helianthus annuus L. were used to study the endoplasmic reticulum (ER) targeting and membrane insertion of this protein both in vitro and in vivo in yeast ( Saccharomyces cerevisiae). Neither the N- nor the C-terminal hydrophilic domains are important for targeting and/or membrane insertion, with all the information required for these processes located within the central hydrophobic region of the protein. However, in vitro membrane-insertion experiments suggest that these domains are important for a correct topology of the oleosin within the ER membrane. The first half of the hydrophobic central domain, flanked by the positively charged N-terminal domain, is likely to function as a type-II signal-anchor (SAII) sequence. However, in the absence of the N-terminal 26 residues of this domain, the proline-knot region and the second half of this hydrophobic domain are sufficient to direct oleosin to the ER and to allow stable (but far less efficient) integration of the protein into the membrane. Taken together, these results indicate that oleosin contains more than one domain that is capable of interacting with the signal recognition particle to direct the protein to the ER membrane.     

The targeting and accumulation of ectopically expressed oleosin in non-seed tissues of Arabidopsis thaliana

 Full-length and N-terminal deletions of a sunflower (Helianthus annuus L.) oleosin protein were expressed ectopically in transgenic Arabidopsis thaliana (L.) Heynh. Immunological detection of the sunflower protein revealed that it accumulated in a range of non-oil-storing tissues, including leaves, roots and petals. This accumulation was shown to result from deposition in the microsomal membrane fraction. Expression in oil-storing tissues (such as seeds) of oleosin N-terminal deletions revealed impaired transfer from the endoplasmic reticulum to the oil body. In non-oil-storing tissues, accumulation in the microsomal membrane fraction was progressively reduced by N-terminal deletion. These data confirm the role of the endomembrane system in the targeting of the oleosin and its intimate relationship with oil-body biogenesis. Received: 26 August 1999 / Accepted: 4 October 1999     

Regulation of SHP-1 tyrosine phosphatase in human platelets by serine phosphorylation at its C terminus

SHP-1 is a Src homology 2 (SH2) domain-containing tyrosine phosphatase that plays an essential role in negative regulation of immune cell activity. We describe here a new model for regulation of SHP-1 involving phosphorylation of its C-terminal Ser591 by associated protein kinase Calpha. In human platelets, SHP-1 was found to constitutively associate with its substrate Vav1 and, through its SH2 domains, with protein kinase Calpha. Upon activation of either PAR1 or PAR4 thrombin receptors, the association between the three proteins was retained, and Vav1 became phosphorylated on tyrosine and SHP-1 became phosphorylated on Ser591. Phosphorylation of SHP-1 was mediated by protein kinase C and negatively regulated the activity of SHP-1 as demonstrated by a decrease in the in vitro ability of SHP-1 to dephosphorylate Vav1 on tyrosine. Protein kinase Calpha therefore critically and negatively regulates SHP-1 function, forming part of a mechanism to retain SHP-1 in a basal active state through interaction with its SH2 domains, and phosphorylating its C-terminal Ser591 upon cellular activation leading to inhibition of SHP-1 activity and an increase in the tyrosine phosphorylation status of its substrates.     

Complete DNA sequence analyses of the first two varicella-zoster virus glycoprotein E (D150N) mutant viruses found in North America: evolution of genotypes with an accelerated cell spread phenotype

Varicella-zoster virus (VZV) is considered to be one of the most genetically stable of all the herpesviruses. Yet two VZV strains with a D150N missense mutation within the gE glycoprotein were isolated in North America in 1998 and 2002. The mutant strains have an accelerated cell spread phenotype, which distinguishes them from all wild-type and laboratory viruses. Since the VZV genome contains 70 additional open reading frames (ORFs), the possibility existed that the phenotypic change was actually due to an as-yet-undiscovered mutation or deletion elsewhere in the genome. To exclude this hypothesis, the entire genomes of the two mutant viruses were sequenced and found to contain 124,883 (VZV-MSP) and 125,459 (VZV-BC) nucleotides. Coding single-nucleotide polymorphisms (SNPs) were identified in 14 ORFs. One missense mutation was discovered in gH, but none was found in gB, gI, gL, or gK. There were no coding SNPs in the major regulatory protein ORF 62. One polymorphism was discovered which could never have been anticipated based on current knowledge of herpesvirus genomics, namely, the origins of replication differed from those in the prototype strain but not in a manner expected to affect cell spread. When the two complete mutant VZV sequences were surveyed in their entirety, the most reasonable conclusion was that the increased cell spread phenotype was dependent substantially or solely on the single D150N polymorphism in glycoprotein gE. The genomic results also expanded the evolutionary database by identifying which VZV ORFs were more likely to mutate over time.     

Alpha-adrenergic vasoconstrictor tone limits right coronary blood flow in exercising dogs

In exercising dogs, increased myocardial O2 consumption (MVO2) of the left ventricle is met primarily by hyperemia, whereas increased O2 extraction makes a greater contribution to right ventricular (RV) O2 supply. We hypothesized that alpha-adrenergic vasoconstrictor tone limits right coronary (RC) blood flow during exercise, forcing increased O2 extraction. This tone might also contribute to lesser RC vascular conductance at rest. Accordingly, RV O2 balance was examined at rest and during graded treadmill exercise before and during alpha-adrenergic blockade with phentolamine (1 mg/kg, i.v., n=6). The transmural distribution of RC flow was measured with radiolabeled microspheres in 4 additional dogs. At rest, alpha-adrenergic receptor blockade did not significantly increase RC flow or conductance. During exercise, alpha-adrenergic blockade increased RC flow and conductance responses to increased RV MVO2 by 25% and 60%, respectively. The transmural distribution of RC flow was not altered by exercise or by alpha-adrenergic blockade. Before alpha-adrenergic blockade, hyperemia provided 39%-66% of the additional O2 consumed by the right ventricle during graded exercise; after alpha-adrenergic blockade, hyperemia contributed 74%-85%. After alpha-adrenergic blockade, the slope of the relationship between RC venous PO2 and RV MVO2 became less steep, reflecting less O2 extraction due to enhanced hyperemia. Additional experiments were conducted on 5 anesthetized, open-chest dogs with constant RC perfusion pressure and beta-adrenergic blockade. The RC flow response to intracoronary norepinephrine was shifted to the left compared with that measured in the left coronary circulation, consistent with observations in the conscious exercising dogs. In conclusion, alpha-adrenergic vasoconstrictor tone does not restrict resting RC blood flow, but during exercise, this tone transmurally blunts RC hyperemia and forces the right ventricle to mobilize its O2 extraction reserve. This effect is more pronounced than has been reported for the left ventricle.     

Mechanisms of oxygen demand/supply balance in the right ventricle

Few studies have investigated factors responsible for the O2 demand/supply balance in the right ventricle. Resting right coronary blood flow is lower than left coronary blood flow, which is consistent with the lesser work of the right ventricle. Because right and left coronary artery perfusion pressures are identical, right coronary conductance is less than left coronary conductance, but the signal relating this conductance to the lower right ventricular O2 demand has not been defined. At rest, the left ventricle extracts approximately 75% of the O2 delivered by coronary blood flow, whereas right ventricular O2 extraction is only ~50%. As a result, resting right coronary venous PO2 is approximately 30 mm Hg, whereas left coronary venous PO2 is approximately 20 mm Hg. Right coronary conductance does not sufficiently restrict flow to force the right ventricle to extract the same percentage of O2 as the left ventricle. Endogenous nitric oxide impacts the right ventricular O2 demand/supply balance by increasing the right coronary blood flow at rest and during acute pulmonary hypertension, systemic hypoxia, norepinephrine infusion, and coronary hypoperfusion. The substantial right ventricular O2 extraction reserve is used preferentially during exercise-induced increases in right ventricular myocardial O2 consumption. An augmented, sympathetic-mediated vasoconstrictor tone blunts metabolically mediated dilator mechanisms during exercise and forces the right ventricle to mobilize its O2 extraction reserve, but this tone does not limit resting right coronary flow. During exercise, right coronary vasodilation does not occur until right coronary venous PO2 decreases to approximately 20 mm Hg. The mechanism responsible for right coronary vasodilation at low PO2 has not been delineated. In the poorly autoregulating right coronary circulation, reduced coronary pressure unloads the coronary hydraulic skeleton and reduces right ventricular systolic stiffness. Thus, normal right ventricular external work and O2 demand/supply balance can be maintained during moderate coronary hypoperfusion.     

Ubiquitylation of the transducin betagamma subunit complex. Regulation by phosducin

G proteins (Galphabetagamma) are essential signaling molecules, which dissociate into Galpha and Gbetagamma upon activation by heptahelical membrane receptors. We have identified the betagamma subunit complex of the photoreceptor-specific G protein, transducin (T), as a target of the ubiquitin-proteasome pathway. Ubiquitylated species of the transducin gamma-subunit (Tgamma) but not the alpha- or beta-subunits were assembled de novo in bovine photoreceptor preparations. In addition, Tgamma was exclusively ubiquitylated when Tbetagamma was dissociated from Talpha. Ubiquitylation of Tbetagamma on Tgamma was selectively catalyzed by human ubiquitin-conjugating enzymes UbcH5 and UbcH7 and was coincident with degradation of the entire Tbetagamma subunit complex in vitro by a mechanism requiring ATP and the proteasome. We also show that Tbetagamma association with phosducin, a photoreceptor-specific protein of unknown physiological function, blocks Tbetagamma ubiquitylation and subsequent degradation. Phosphorylation of phosducin by Ca(2+)/calmodulin-dependent protein kinase II, which inhibits phosducin-Tbetagamma complex formation, completely restored Tbetagamma ubiquitylation and degradation. We conclude that Tbetagamma is a substrate of the ubiquitin-proteasome pathway and suggest that phosducin serves to protect Tbetagamma following the light-dependent dissociation of Talphabetagamma.     

C-reactive protein does not relax vascular smooth muscle: effects mediated by sodium azide in commercially available preparations

C-reactive protein (CRP), an acute-phase protein and newly recognized indicator of cardiovascular risk, may have direct actions on the vascular wall. Previous studies suggest that CRP is a vasodilator that activates smooth muscle K(+) channels. We examined the reported vasoactive properties of CRP and further explored its mechanisms of action. CRP decreased blood pressure in rats and increased coronary flow in open-chest dogs at a constant coronary perfusion pressure. CRP relaxed rat aortic rings and mesenteric small arteries that were contracted with phenylephrine. Relaxation was not affected by endothelial denudation or inhibition of nitric oxide (NO) synthase but was blocked by inhibition of soluble guanylate cyclase or K(+) channels. CRP solutions remained effective, i.e., elicited vasodilation, even after boiling or enzymatic digestion, which suggests the presence of a nonprotein contaminant. Sodium azide (NaN(3), 0.1%) is the preservative used for commercially available CRP and a potential source of NO. NaN(3) elicited the same cardiovascular effects as CRP preparations at equal concentrations, and its actions were blocked by inhibition of guanylate cyclase and K(+) channels. NaN(3)-free CRP, prepared by gel-filtration centrifugation and confirmed by electrophoresis, had no effect on vascular tone. Inhibition of vascular smooth muscle catalase with 3-amino-1,2,4-triazole completely prevented the effects of NaN(3) and NaN(3)-containing CRP solutions. We demonstrate that the acute vasoactive properties of commercially available CRP preparations are attributable to NaN(3) (and subsequent production of NO by catalase); therefore, this study suggests a reappraisal of the acute role of CRP in regulating vascular tone.