Studies on the diterpenes of Helianthus annuus : identification of a new gibberellin and preparation of protein conjugates of kaurenoids

Singh, A. K.

January 1987

No description available.

572

Sunflower biosynthesis

Synthetic studies on C3̲0̲ botryococcene

Hird, N. W.

January 1988

No description available.

572

Biosynthesis of botryococcenes

Studies on a type II polyketide synthase : a chain initiation factor

Westcott, James

January 2001

No description available.

572

Ketosynthase, Biosynthesis

The synthesis and metabolism of some novel gibberellins and related compounds

Makinson, Ian Kenneth

January 1988

No description available.

572

Gibberellin biosynthesis

Biosynthesis of the microbial metabolites xenovulene A and XR 587 : novel rearrangement and ring formation pathways

Raggatt, Mairi E.

January 1998

No description available.

547

Polyketide biosynthesis

The conversion of sucrose to starch in the developing wheat grain

Tyson, R. H.

January 1987

No description available.

572

Biosynthesis of starch

Synthesis of deoxyhypusine in eukaryotic initiation factor 4D in rat hepatoma cells.

Murphey, Roberta Jean.

January 1989

The aim of this research was to study the mechanism involved in the synthesis of deoxyhypusine, the intermediate step in the synthesis of the amino acid hypusine. Oeoxyhypusine is derived from the butylamine moiety of a spermidine molecule which is added to the famino group of one lysine in the eukaryotic initiation factor 40 (eIF-4D). Initially, a hepatoma tissue cell (HTC) lysate with a pH of 9.5 in glycine buffer and with a depleted spermidine pool supported deoxyhypusine synthesis in protein. Since CHES buffer was as efficient as glycine buffer, the synthesis of deoxyhypusine was pH dependent (optimum ∼9.2) and not buffer dependent. Next, several inhibitors were used in the cell-free system to block deoxyhypusine synthesis. Only guazatine, a plant amine oxidase inhibitor, completely inhibited deoxyhypusine synthesis. This suggested that an oxidase was involved in deoxyhypusine synthesis. In addition factors were investigated as possible allosteric stimulators of deoxyhypusine formation. NAD⁺, NADH, FAD⁺, FMN⁺, and as nicotinamide were tested for effects on deoxyhypusine formation. NAD⁺ was the most efficient stimulator, but NAOH and nicotinamide also stimulated deoxyhypusine formation. Although these factors increased the synthesis of deoxyhypusine, these assays were done in buffer with low concentrations of spermidine. When the spermidine pool was replenished, these effects were diminished. Thus, it appeared that NAD⁺ may lower the apparent K(m) for spermidine without affecting the V(max) of deoxyhypusine synthesis. The inhibition of deoxyhypusine synthesis by guazatine implied the involvement of a polyamine oxidase. Therefore, the effect of oxygen depletion on deoxyhypusine formation was investigated. The depletion of oxygen reduced the level of deoxyhypusine synthesis to 12% of the control. This activity could be restored to 85% by reoxygenation of the lysate. Thus in support of the suggestion made by the guazatine data, a spermidine oxidase in involved in deoxyhypusine formation. The most significant contribution of this work was the development of a cell free system to study deoxyhypusine. This synthesis required an unusually high pH in vitro and required polyamine depletion (Chapter 2). In addition, synthesis requires a unique spermidine oxidase that is blocked by a guazatine and is conditionally stimulated by NAD⁺ (Chapter 3).

Amino acids -- Synthesis.

Biosynthesis.

Molecular mechanism of enhanced induced mutagenesis in aprt-deficient mutant subclones of friend mouse erythroleukaemia cells

Yadollahi-Farsani, Masoud

January 1993

No description available.

572.8

Nucleotide biosynthesis

The biochemical and structural basis of transcription regulation by CysB protein

Addy, Christine

January 1999

No description available.

572

Cystein biosynthesis

The role of cathepsin L in elastin degradation

Wilcox, Donna

January 1990

No description available.

572

Biosynthesis of cysteine proteinases