Retroelement insertions at the Medicago FTa1 locus in spring mutants eliminate vernalisation but not long-day requirements for early flowering.

Molecular-genetic control of the flowering time of temperate-climate plants is best understood in Arabidopsis and the cereals wheat and barley. However, key regulators such as FLC and cereal VRN2 are not found in legumes. Therefore, we used forward genetics to identify flowering time genes in the model legume Medicago truncatula (Medicago) which is induced to flower by vernalisation and long-day photoperiods. A screen of a Tnt1 retroelement tagging population yielded two mutants, spring2 and spring3, with a dominant early flowering phenotype. These mutants overexpress the floral activator FTa1 and two candidate downstream flowering genes SOC1a and FULb, similar to the spring1 somaclonal variant that we identified previously. We demonstrate here that an increase in the expression of FTa1, SOC1a and FULb and early flowering does not occur in all conditions in the spring mutants. It depends on long-day photoperiods but not on vernalisation. Isolation of flanking sequence tags and linkage analysis identified retroelement insertions at FTa1 that co-segregated with the early flowering phenotype in all three spring mutants. These were Tnt1 insertions in the FTa1 third intron (spring3) or the 3' intergenic region (spring2) and an endogenous MERE1-4 retroelement in the 3' intergenic region in spring1. Thus the spring mutants form an allelic series of gain-of-function mutations in FTa1 which confer a spring growth habit. The spring retroelement insertions at FTa1 separate long-day input from vernalisation input into FTa1 regulation, but this is not due to large-scale changes in FTa1 DNA methylation or transcript processing in the mutants.

Metabolic proteomics of the liver and mammary gland during lactation.

The liver and the mammary gland have complementary metabolic roles during lactation. Glucose synthesized by the liver is released into the circulation and is taken up by the mammary gland where major metabolic products of glucose include milk sugar (lactose) and the glycerol backbone of milk fat (triglycerides). Hepatic synthesis of glucose is often accompanied by ß-oxidation in that organ to provide energy for glucose synthesis, while mammary gland synthesizes rather than oxidizes fat during lactation. We have therefore compared enzyme abundances between the liver and mammary gland of lactating Friesian cows where metabolic output is well established. Quantitative differences in protein amount were assessed using two-dimensional differential in-gel electrophoresis. As predicted, the abundances of enzymes catalysing gluconeogenesis and ß-oxidation were greatest in the liver, and enzyme abundances in mammary tissue were consistent with fat synthesis rather than ß-oxidation.

Expression, purification and characterisation of GIGANTEA: a circadian clock-controlled regulator of photoperiodic flowering in plants.

The Arabidopsis thaliana (Arabidopsis) GIGANTEA (GI) gene is a central component of the photoperiodic flowering pathway. While it has been 40 years since the first mutant alleles of GI were described much is still unknown about the molecular mechanism of GI action. To investigate the biochemistry and domain organisation (and ultimately to give a greater understanding of the role of GI in floral induction), it is first necessary to produce significant quantities of purified protein. Soluble affinity-tagged full-length GI was expressed in Escherichia coli (E. coli) and was stabilised by the addition of the detergent n-dodecyl-ß-D-maltoside (DDM) to storage and purification buffers. Stabilised GI was purified using a variety of chromatographic methods, and characterised using a selection of biochemical techniques including circular dichroism, and dynamic light scattering. This showed that purified GI contained secondary structure, but was polydisperse in solution. Electron microscopy suggests a possible tetramer arrangement of GI. Limited proteolytic digests and mass spectrometry were used to identify potential GI domains. This led to the identification of a predicted 46 kDa amino-terminal GI domain. GI was also expressed in Sf9 insect cells using the baculovirus expression system. GI produced via this route gave insoluble protein.

The gene MACCHI-BOU 4/ENHANCER OF PINOID encodes a NPH3-like protein and reveals similarities between organogenesis and phototropism at the molecular level.

Intercellular transport of the phytohormone auxin is a significant factor for plant organogenesis. To investigate molecular mechanisms by which auxin controls organogenesis, we analyzed the macchi-bou 4 (mab4) mutant identified as an enhancer of pinoid (pid). Although mab4 and pid single mutants displayed relatively mild cotyledon phenotypes, pid mab4 double mutants completely lacked cotyledons. We found that MAB4 was identical to ENHANCER OF PINOID (ENP), which has been suggested to control PIN1 polarity in cotyledon primordia. MAB4/ENP encodes a novel protein, which belongs to the NON-PHOTOTROPIC HYPOCOTYL 3 (NPH3) family thought to function as a signal transducer in phototropism and control lateral translocation of auxin. MAB4/ENP mRNA was detected in the protodermal cell layer of the embryo and the meristem L1 layer at the site of organ initiation. In the mab4 embryo, the abundance of PIN1:GFP was severely decreased at the plasma membrane in the protodermal cell layer. In addition, subcellular localization analyses indicated that MAB4/ENP resides on a subpopulation of endosomes as well as on unidentified intracellular compartments. These results indicate that MAB4/ENP is involved in polar auxin transport in organogenesis.