A Brassica S locus gene promoter directs sporophytic expression in the anther tapetum of transgenic Arabidopsis

The S locus glycoprotein (SLG) gene of Brassica encodes stigmatic glycoproteins that are implicated in the pollen-stigma interaction of self-incompatibility. We have transformed the related plant Arabidopsis thaliana with a chimaeric gene consisting of the promoter region of an SLG gene fused to the reporter gene beta-glucuronidase (GUS). In transgenic plants the gene was expressed in two cell types of the flower. In stigmas, the timing and distribution of GUS activity was similar to that previously described for SLG expression in Brassica. In anthers, expression was detected at an earlier stage of flower development with GUS activity restricted to the tapetal cell layer. The novel finding of SLG-promoter activity in the anther supports the hypothesis that sporophytic control of self-incompatibility is a result of SLG-gene expression in the tapetum.     

High pressure freezing and freeze substitution improve immunolabeling of S-locus specific glycoproteins in the stigma papillae ofBrassica

Summary High pressure freezing and freeze substitution methods significantly improve the antigenic preservation of S-locus specific glycoproteins (SLSG). The SLSG, which are implicated in the incompatibility response, are localized over the cell wall and cytoplasm. Labeling in the cytoplasm is mainly associated with dictyosomes and rough endoplasmic reticulum. Quantitative analysis show that in cryofixed papillae the labeling was enhanced by approximately 45% over the cell wall and approximately 90% over the dictyosomes compared to chemically fixed papillae.     

A Brassica Self-Incompatibility Gene Is Expressed in the Stylar Transmitting Tissue of Transgenic Tobacco

Tobacco was transformed with a gene coding for an S-locus-specific glycoprotein of Brassica oleracea. The resulting transgenic plants showed tissue-specific and developmentally regulated expression of the introduced gene. Immunolocalization experiments showed that the Brassica gene was expressed in the stylar transmitting tissue of the transgenic plants. The pattern of expression of the introduced gene was more similar to that of the S-associated genes of Nicotiana alata than to expression in Brassica. Self-incompatibility was not conferred by the introduced gene.     

Locus-specific ribosomal RNA gene silencing in nucleolar dominance

The silencing of one parental set of rRNA genes in a genetic hybrid is an epigenetic phenomenon known as nucleolar dominance. We showed previously that silencing is restricted to the nucleolus organizer regions (NORs), the loci where rRNA genes are tandemly arrayed, and does not spread to or from neighboring protein-coding genes. One hypothesis is that nucleolar dominance is the net result of hundreds of silencing events acting one rRNA gene at a time. A prediction of this hypothesis is that rRNA gene silencing should occur independent of chromosomal location. An alternative hypothesis is that the regulatory unit in nucleolar dominance is the NOR, rather than each individual rRNA gene, in which case NOR localization may be essential for rRNA gene silencing. To test these alternative hypotheses, we examined the fates of rRNA transgenes integrated at ectopic locations. The transgenes were accurately transcribed in all independent transgenic Arabidopsis thaliana lines tested, indicating that NOR localization is not required for rRNA gene expression. Upon crossing the transgenic A. thaliana lines as ovule parents with A. lyrata to form F1 hybrids, a new system for the study of nucleolar dominance, the endogenous rRNA genes located within the A. thaliana NORs are silenced. However, rRNA transgenes escaped silencing in multiple independent hybrids. Collectively, our data suggest that rRNA gene activation can occur in a gene-autonomous fashion, independent of chromosomal location, whereas rRNA gene silencing in nucleolar dominance is locus-dependent.     

Independent S-Locus Mutations Caused Self-Fertility in Arabidopsis thaliana

A common yet poorly understood evolutionary transition among flowering plants is a switch from outbreeding to an inbreeding mode of mating. The model plant Arabidopsis thaliana evolved to an inbreeding state through the loss of self-incompatibility, a pollen-rejection system in which pollen recognition by the stigma is determined by tightly linked and co-evolving alleles of the S-locus receptor kinase (SRK) and its S-locus cysteine-rich ligand (SCR). Transformation of A. thaliana, with a functional AlSRKb-SCRb gene pair from its outcrossing relative A. lyrata, demonstrated that A. thaliana accessions harbor different sets of cryptic self-fertility–promoting mutations, not only in S-locus genes, but also in other loci required for self-incompatibility. However, it is still not known how many times and in what manner the switch to self-fertility occurred in the A. thaliana lineage. Here, we report on our identification of four accessions that are reverted to full self-incompatibility by transformation with AlSRKb-SCRb, bringing to five the number of accessions in which self-fertility is due to, and was likely caused by, S-locus inactivation. Analysis of S-haplotype organization reveals that inter-haplotypic recombination events, rearrangements, and deletions have restructured the S locus and its genes in these accessions. We also perform a Quantitative Trait Loci (QTL) analysis to identify modifier loci associated with self-fertility in the Col-0 reference accession, which cannot be reverted to full self-incompatibility. Our results indicate that the transition to inbreeding occurred by at least two, and possibly more, independent S-locus mutations, and identify a novel unstable modifier locus that contributes to self-fertility in Col-0.     

A metabonomic study of inhibition of GABA uptake in the cerebral cortex

GABAergic activity is regulated by rapid, high affinity uptake of GABA from the synapse. Perturbation of GABA reuptake has been implicated in neurological disease and inhibitors of GABA transporters (GAT) have been used therapeutically but little detail is known about the ramifications of GAT inhibition on brain neurochemistry. Here, we incubated Guinea pig cortical tissue slices with [3-¹³C]pyruvate and major, currently available GABA uptake inhibitors. Metabolic fingerprints were generated from these experiments using ¹³C/¹H NMR spectroscopy. These fingerprints were analyzed using multivariate statistical approaches and compared with an existing library of fingerprints of activity at GABA receptors. This approach identified five distinct clusters of metabolic activity induced by blocking GABA uptake. Inhibition of GABA uptake via GAT1 produced patterns similar to activity at mainstream GABAergic synapses in particular those containing α1-subunits but still statistically separable. This indicated that inhibition of GABA uptake, an indirect method of activating GABA receptors, produces different effects to direct receptor activation or to exogenous GABA. The mechanism of inhibitor function also produced different outcomes, with the channel blocker SKF 89976A yielding a unique metabolic response. Blocking GAT1 and GAT3 simultaneously induces a large metabolic response consistent with induction of tonic inhibition via high affinity GABA receptors. Blocking BGT produces patterns similar to activity at less common receptors such as those containing α5 subunits. This approach is useful for determining where in the spectrum of GABAergic responses a particular GABA transport inhibitor is effective.