H. Maelor Davies

A specific acyl-ACP thioesterase implicated in medium-chain fatty acid production in immature cotyledons of Umbellularia californica

Umbellularia californica (California Bay) seeds accumulate 10:0 and 12:0 as principal reserve fatty acyl groups. An in vitro fatty acid synthesis system from the developing cotyledons produces chiefly 10:0 and 12:0, in approximately the same proportions as the intact tissue. The kinetics of acyl thioester and free fatty acid formation in this system suggest that a medium-chain specific acyl-acyl-carrier protein (ACP) hydrolysis mechanism is responsible for the preponderance of medium-chain products. A crude extract of the developing cotyledons exhibits hydrolytic activity toward acyl-ACPs, with marked preference for 12:0-ACP and 18:1-ACP in the test series 6:0, 8:0, 10:0, 11:0, 12:0, 14:0, 16:0, and 18:1-ACPs. Partial purification of the 12:0-ACP hydrolytic activity has resulted in its separation from the 18:1-ACP hydrolase(s) and the 12:0-coenzyme A hydrolase(s) that are also present, thereby demonstrating its specificity for the 12-carbon acyl chain length and the ACP derivative. During cotyledon development, as the proportion of medium-chain to other fatty acyl groups increases, the extractable yield of this activity also increases substantially. Collectively these results suggest a role for this 12-ACP thioesterase in medium-chain production in vivo.

Developmental induction, purification, and further characterization of 12:0-ACP thioesterase from immature cotyledons of Umbellularia californica

The fatty acyl content of developing cotyledons of Umbellularia californica (California Bay) changes from a long-chain composition to a predominance of 10:0 and 12:0 in just 4-5 days at the beginning of an approximately 100-day period of medium-chain deposition. This striking change occurs at the earliest appearance of 12:0-acyl-carrier protein (ACP) thioesterase activity. The coincidence of these rapid events is consistent with the hypothesis that the enzyme plays a major role in medium-chain biosynthesis. The 12:0-ACP thioesterase has been substantially purified; enzyme activity consistently comigrates in chromatographic and electrophoretic systems with a protein or pair of proteins having an apparent molecular weight of approximately 34 kDa. A native molecular weight of approximately 42 kDa has been estimated by gel filtration chromatography, suggesting that the enzyme is a monomer. Affinity chromatography on immobilized ACP is a critical step in the purification procedure, and resolves the 12:0-ACP and 18:1-ACP thioesterases sufficiently to confirm that the medium-chain enzyme has negligible action on 18:1-ACP.

Lysophosphatidic acid acyltransferase from immature coconut endosperm having medium chain length substrate specificity

Abstract Immature endosperm of coconut ( Cocos nucifera ) contains a membrane-bound lysophosphatidic acid acyltransferase (LPAAT) having medium chain length substrate specificity appropriate to the biosynthesis of coconut oil. Acyl-CoAs containing 10:0, 12:0 and 14:0 acyl groups are the preferred acyl-donor substrates; acyl-ACPs are not utilized. There is slight preference for 12:0-lysophosphatidic acid (LPA) over 18:1-LPA as acceptor substrate. Treatment of the active membrane fraction with 2.25% (w/v) CHAPS, at a detergent:protein ratio of 48:1 (w/v), in the presence of 1M NaCl solubilized the enzyme in high yield. Solubilization was evidenced by three independent criteria, namely, failure of the activity to sediment at high centrifugal force, behaviour of the activity as a globular protein of apparent M r 44000 in size-exclusion chromatography, and partial resolution of the activity from many of the membrane proteins on the size-exclusion column. Optimal restoration of LPAAT activity after solubilization required the addition of detergent-treated phospholipids, in addition to a lowering of the detergent and NaCl concentrations.

Increased pathogen resistance and yield in transgenic plants expressing combinations of the modified antimicrobial peptides based on indolicidin and magainin

Reverse peptide of indolicidin (Rev4), a 13-residue peptide based on the sequence of indolicidin, has been shown to possess both strong antimicrobial and protease inhibitory activities in vitro. To evaluate its efficacy in vivo, we produced and evaluated transgenic tobacco (Nicotiana tabacum L.) and Arabidopsisthaliana [(L.) Heynh.] plants expressing Rev4 with different signal peptide sequences for pathogen resistance. All transgenic plants showed normal growth and development, an indication of no or low cytotoxicity of the peptide. Furthermore, the transgenic plants exhibited elevated resistance to three bacterial and two oomycete pathogens. Interestingly, tobacco plants expressing Rev4 displayed enhanced yield compared to the control as indicated by an increased biomass production by as much as 34% in two field trials. When Rev4 was coexpressed with another antimicrobial peptide, Myp30, the disease resistance levels in the transgenic Arabidopsis were enhanced. These findings suggest the potential of using these peptides to protect plants from microbial pathogens and to enhance yield.

A tridecapeptide possesses both antimicrobial and protease-inhibitory activities.

A 13-residue synthetic peptide (Rev4) was designed based on indolicidin, an antimicrobial peptide from bovine neutrophils. The synthetic peptide retains high antimicrobial activity. When tested for its stability in tobacco leaf extracts, Rev4 was highly stable compared to another antimicrobial peptide, magainin. When mixed with Rev4, magainin was protected from degradation by the leaf extract. Our results show that Rev4 is a potent protease inhibitor which selectively inhibits three out of four different types of proteases. Four other synthetic peptides were tested and the results were suggestive of no correlation between their antimicrobial and protease inhibitory activities.

Biochemical observations on medium-chain-length polyhydroxyalkanoate biosynthesis and accumulation in Pseudomonas mendocina.

Certain Pseudomonads are capable of accumulating high levels of medium-chain-length polyhydroxyalkanates (PHAmcl) when grown with carbohydrates as the main carbon source. 3-OH acyl components of PHAmcl are derived from fatty acid synthase (FAS) and these components are accessed by action of 3-hydroxyacyl-acyl carrier protein (ACP)-coenzyme A (CoA) transferase (transacylase). However, little is known with regard to the time courses of 3-OH acyl component occurrence and of transacylase activity during PHAmcl induction. Also, little is known with regard to the coupling mechanism between FAS and PHAmcl synthesis or whether the FAS pathway itself is specialized in PHAmcl-producing cells. Our results with regard to the time course of formation of 3-OH acids, 3-OH acyl-ACPs, and PHAmcl are consistent with the view that transacylase provides the key link between FAS and PHAmcl synthase. They also suggest that FAS specialization is not a feature of the mechanism. Further, we observed the formation of a 3-OH 10:0 homopolymer early in the induction phase followed by later formation of a mixed polymer containing 3-OH 8:0 and 3-OH 12:0 in addition to 3-OH 10:0. Early occurrence of 3-OH 10:0-CoA transacylase activity was coincident with homopolymer formation.

EVALUATION OF FLOAT TRAYS WITH HIGH CELL NUMBERS ON STAND COUNTS AND YIELDS IN A CLOSE-GROWN TOBACCO PRODUCTION SYSTEM

Abstract New applications for tobacco plants as manufacturing systems for medical and industrial products are in a sufficiently advanced stage of development that attention is now being directed at the efficiency and cost effectiveness of crop production. The greenhouse costs associated with raising transplants are an important factor, partly because the high planting density of these new tobacco crops in the field will greatly increase the number of transplants needed per unit area of production, and thus the overall cost of the crop, and partly because the transgenic transplants that will be used in some strategies will need to be raised in more stringently quarantined greenhouse facilities according to governmental regulations. Thus minimizing the square footage of greenhouse space for the production of transplants is a desirable objective. The float-bed system that is now widely used to produce tobacco transplants can physically accommodate a higher transplant density than is conventionally employed, ...

Assessing the bioconfinement potential of a Nicotiana hybrid platform for use in plant molecular farming applications

BackgroundThe introduction of pharmaceutical traits in tobacco for commercial production could benefit from the utilization of a transgene bioconfinement system. It has been observed that interspecific F1Nicotiana hybrids (Nicotiana tabacum × Nicotiana glauca) are sterile and thus proposed that hybrids could be suitable bioconfined hosts for biomanufacturing. We genetically tagged hybrids with green fluorescent protein (GFP), which was used as a visual marker to enable gene flow tracking and quantification for field and greenhouse studies. GFP was used as a useful proxy for pharmaceutical transgenes.ResultsAnalysis of DNA content revealed significant genomic downsizing of the hybrid relative to that of N. tabacum. Hybrid pollen was capable of germination in vitro, albeit with a very low frequency and with significant differences between plants. In two field experiments, one each in Tennessee and Kentucky, we detected outcrossing at only one location (Tennessee) at 1.4%. Additionally, from 50 hybrid plants at each field site, formation of 84 and 16 seed was observed, respectively. Similar conclusions about hybrid fertility were drawn from greenhouse crosses. In terms of above-ground biomass, the hybrid yield was not significantly different than that of N. tabacum in the field.ConclusionN. tabacum × N. glauca hybrids show potential to contribute to a bioconfinement- and biomanufacturing host system. Hybrids exhibit extremely low fertility with no difference of green biomass yields relative to N. tabacum. In addition, hybrids are morphologically distinguishable from tobacco allowing for identity preservation. This hybrid system for biomanufacturing would optimally be used where N. glauca is not present and in physical isolation of N. tabacum production to provide total bioconfinement.