Philip M. Gilmartin

Arabidopsis Co-expression Tool (ACT): web server tools for microarray-based gene expression analysis.

The Arabidopsis Co-expression Tool, ACT, ranks the genes across a large microarray dataset according to how closely their expression follows the expression of a query gene. A database stores pre-calculated co-expression results for ∼21 800 genes based on data from over 300 arrays. These results can be corroborated by calculation of co-expression results for user-defined sub-sets of arrays or experiments from the NASC/GARNet array dataset. Clique Finder (CF) identifies groups of genes which are consistently co-expressed with each other across a user-defined co-expression list. The parameters can be altered easily to adjust cluster size and the output examined for optimal inclusion of genes with known biological roles. Alternatively, a Scatter Plot tool displays the correlation coefficients for all genes against two user-selected queries on a scatter plot which can be useful for visual identification of clusters of genes with similar r-values. User-input groups of genes can be highlighted on the scatter plots. Inclusion of genes with known biology in sets of genes identified using CF and Scatter Plot tools allows inferences to be made about the roles of the other genes in the set and both tools can therefore be used to generate short lists of genes for further characterization. ACT is freely available at .

Wind-borne insects mediate directional pollen transfer between desert fig trees 160 kilometers apart

The question of how far pollen can move between plants has implications for topics as diverse as habitat fragmentation, conservation management, and the containment of genetically modified crops. The monoecious African fig tree Ficus sycomorus L. relies on the small, short-lived, night-flying, host-specific fig wasp Ceratosolen arabicus Mayr for pollination. We used microsatellite markers to characterize a geographically isolated riparian population of F. sycomorus growing along the Ugab River in the Namib Desert, Namibia, together with paternity analysis of seedlings from known mothers, to map pollen movement within this population. In this way we tracked insect movements between individually recognizable trees by means of their pollen cargo and documented the movement of C. arabicus between known trees separated by more than 160 km, with a mean distance for confirmed successful pollination events of 88.6 km. The predominant observed movement of pollinators was in a westerly direction, toward the sea, reflecting seasonal nighttime wind direction and the wind-borne dispersal of fig wasps. Our results suggest the existence of an extensive panmictic population of trees that are well suited to overcome the effects of geographical isolation.

Characterization of a Gene Encoding a DNA Binding Protein with Specificity for a Light-Responsive Element

The sequence element of box II (GTGTGGTTAATATG) is a regulatory component of a light-responsive element present within the upstream region of pea rbcS-3A. The nuclear protein GT-1 was defined previously as a DNA binding activity that interacts with box II. Here, we describe the isolation and characterization of cDNA sequences that encode a DNA binding protein with specificity for this element. The recombinant protein, tobacco GT-1a, shows similar sequence requirements for DNA binding to nuclear GT-1, as assayed by its ability to interact with previously defined 2-bp scanning mutations of box II, and is shown to be immunologically related to nuclear GT-1. The predicted structure of the 43-kD protein derived from the cDNA sequence suggests the presence of a novel helix-helix-turn-helix (HHTH) motif. Comparison between the predicted protein sequence encoded by the tobacco GT-1a cDNA and that of another GT binding protein, rice GT-2, reveals strong amino acid conservation over the HHTH region; this motif appears to be involved in the interaction between the recombinant protein and box II. Genomic DNA gel blot analysis indicated the presence of a small gene family of related sequences within the tobacco nuclear genome. RNA gel blot analysis of tobacco mRNA using the isolated cDNA as a probe showed that transcripts are present in several tissues, including both light-grown and dark-adapted leaves.

A Metal-Dependent DNA-Binding Protein Interacts with a Constitutive Element of a Light-Responsive Promoter

We have used DNase I footprinting to characterize nuclear factors that bind to the light-responsive promoter of pea rbcS-3A, one member of the gene family encoding the small subunit of ribulose-1,5-bisphosphate carboxylase. A sequence-specific binding activity, designated 3AF1, binds to an AT-rich sequence present at the -45 region of the rbcS-3A promoter. A tetramer of the 3AF1 binding site, designated as Box VI, can form multiple complexes with tobacco leaf and root nuclear extracts. Mutations of 3 base pairs in Box VI severely reduce DNA-protein complex formation in vitro. The wild-type Box VI tetramer, but not the mutant tetramer, is active in transgenic tobacco plants when placed upstream of the cauliflower mosaic virus 35S promoter truncated at -90. These results correlate binding of 3AF1 to the in vivo function of Box VI. The Box VI tetramer/35S chimeric construct confers expression in diverse cell types and organs and its activity is not dependent on light. By using the Box VI tetramer as a probe to screen a cDNA expression library, we have obtained a putative cDNA clone for the 3AF1 DNA-binding activity. Lysogen extracts of Escherichia coli expressing the cDNA clone give sequence-specific complexes with Box VI. The deduced amino acid sequence of the protein encoded by the cDNA contains two stretches of about 100 residues that are 80% homologous. Moreover, in each of the two repeats, there is an arrangement of histidines and cysteines, which may be related to the two known types of zinc-finger motifs found in many DNA-binding proteins. Consistent with the expectation that metal coordination plays an important role in DNA binding by this protein, we found that 1,10-phenanthroline can abolish the formation of DNA-protein complexes. Interestingly, we found that the same treatment did not abolish the DNA binding activity of 3AF1 in crude nuclear extracts of tobacco. These data indicate that the nuclear 3AF1 activity is likely due to multiple DNA-binding proteins all interacting with Box VI in vitro. RNA gel blot analysis shows that multiple transcripts homologous to this cDNA clone are expressed in different tobacco organs.

Conservation, Convergence, and Divergence of Light-Responsive, Circadian-Regulated, and Tissue-Specific Expression Patterns during Evolution of the Arabidopsis GATA Gene Family

In vitro analyses of plant GATA transcription factors have implicated some proteins in light-mediated and circadian-regulated gene expression, and, more recently, the analysis of mutants has uncovered further diverse roles for plant GATA factors. To facilitate function discovery for the 29 GATA genes in Arabidopsis (Arabidopsis thaliana), we have experimentally verified gene structures and determined expression patterns of all family members across adult tissues and suspension cell cultures, as well as in response to light and signals from the circadian clock. These analyses have identified two genes that are strongly developmentally light regulated, expressed predominantly in photosynthetic tissue, and with transcript abundance peaking before dawn. In contrast, several GATA factor genes are light down-regulated. The products of these light-regulated genes are candidates for those proteins previously implicated in light-regulated transcription. Coexpression of these genes with well-characterized light-responsive transcripts across a large microarray data set supports these predictions. Other genes show additional tissue-specific expression patterns suggesting novel and unpredicted roles. Genome-wide analysis using coexpression scatter plots for paralogous gene pairs reveals unexpected differences in cocorrelated gene expression profiles. Clustering the Arabidopsis GATA factor gene family by similarity of expression patterns reveals that genes of recent descent do not uniformly show conserved current expression profiles, yet some genes showing more distant evolutionary origins have acquired common expression patterns. In addition to defining developmental and environmental dynamics of GATA transcript abundance, these analyses offer new insights into the evolution of gene expression profiles following gene duplication events.

Spacing between GT-1 binding sites within a light-responsive element is critical for transcriptional activity.

Dissection of the light-responsive element (LRE) located between -166 and -50 of rbcS-3A from pea has revealed critical spacing requirements between the two GT-1 binding sites for light-responsive transcription. An increase in spacing between the two sites by as little as 2 bp reduces dramatically the rbcS-3A transcript levels in vivo. Mutation of the 10 bp between the binding sites leads to slightly lower transcript levels, as do deletions of either 3 bp or 8 bp. Deletions of 5 bp or 7 bp from between the GT-1 binding sites do not affect rbcS-3A transcript levels; however, a deletion of 10 bp virtually abolishes the activity of this element. These spacing changes within the light-responsive element similarly affect transcription of a divergently oriented and truncated nopaline synthase promoter. Most spacing changes between the two GT-1 binding sites, however, do not impair the binding of GT-1 to this element in vitro. Together with previous observations, these results suggest that the nuclear factor GT-1 may interact with the binding sites in either a productive or nonproductive manner and that GT-1 binding is necessary but not sufficient for light-responsive transcription. We also discuss our results in relation to the observed spacing of similar sequence elements present within other light-responsive promoters.

Sex determination in dioecious Silene latifolia:Effects of the Y chromosome and the parasitic smut fungus (Ustilago violacea) on gene expression during flower development

We have embarked on a molecular cloning approach to the investigation of sex determination in Silene Iatifolia Poiret, a dioecious plant species with morphologically distinguishable sex chromosomes. One of our key objectives was to define a range of genes that are up-regulated in male plants in response to Y chromosome sex-determination genes. Here we present the characterization of eight male-specific cDNA sequences and classify these according to their expression dynamics to provide a range of molecular markers for dioecious male flower development. Genetically female S. latifolia plants undergo a partial sex reversal in response to infection by the parasitic smut fungus Ustilago violacea. This phenomenon has been exploited in these studies; male-specific cDNAs have been further categorized as inducible or noninducible in female plants by smut fungus infection. Analysis of the organ-specific expression of male-specific probes in male and female flowers has also identified a gene that is regulated in a sex-specific manner in nonreproductive floral tissues common to both male and female plants. This observation provides, to our knowledge, the first molecular marker for dominant effects of the Y chromosome in nonreproductive floral organs.

The molecular biology of photoregulated genes

In the last two decades a great deal of data has accumulated which shows that gene expression is very often under phytochrome control during de-etiolation and re-etiolation of young seedlings (for recent reviews see chapters in: Thomas and Johnson 1991). It is also well documented that some photomovements (polarotropism of some ferns and mosses and chloroplast orientation in the alga Mougeotia) are under phytochrome control (Chapters 7.2, 9.4 and 9.8). In these cases an action dichroism can be demonstrated which has been taken as an indication that phytochrome may act as a membrane effector. Wagner and his colleagues (1984) and Serlin and Roux (1984) have demonstrated the involvement of Ca2+, calmodulin and actin filaments in the signal transduction process between the far-red light (FR)-absorbing form of phytochrome (Pfr) and chloroplast turning. Phytochrome localization (Chapter 4.5), photomovement (Chapter 9.4), and phytochrome and membranes (Chapter 4.6), will be discussed elsewhere in this book. Here we will concentrate on the question as to what is known about the mode of phytochrome action on gene expression. Before treating this problem, some general kinetic properties of phytochrome, signal transduction and underlying developmental programs will be discussed.

Genetic architecture and evolution of the S locus supergene in Primula vulgaris

Darwins studies on heterostyly in Primula described two floral morphs, pin and thrum, with reciprocal anther and stigma heights that promote insect-mediated cross-pollination. This key innovation evolved independently in several angiosperm families. Subsequent studies on heterostyly in Primula contributed to the foundation of modern genetic theory and the neo-Darwinian synthesis. The established genetic model for Primula heterostyly involves a diallelic S locus comprising several genes, with rare recombination events that result in self-fertile homostyle flowers with anthers and stigma at the same height. Here we reveal the S locus supergene as a tightly linked cluster of thrum-specific genes that are absent in pins. We show that thrums are hemizygous not heterozygous for the S locus, which suggests that homostyles do not arise by recombination between S locus haplotypes as previously proposed. Duplication of a floral homeotic gene 51.7 million years (Myr) ago, followed by its neofunctionalization, created the current S locus assemblage which led to floral heteromorphy in Primula. Our findings provide new insights into the structure, function and evolution of this archetypal supergene.

A comparison of early floral ontogeny in wild-type and floral homeotic mutant phenotypes of Primula.

Abstract.Primula flowers are heteromorphic with individual plants producing either pin-form or thrum-form flowers. We have used scanning electron microscopy to observe early development of wild-type flowers of primrose (Primula vulgaris), cowslip (P. veris), and the polyanthus hybrid (P. × tommasinii × P. vulgaris). Floral ontogeny in Primula is different from that observed in the well-studied models Antirrhinum majus and Arabidopsis thaliana and our studies reveal morphological landmark events that define the sequence of early floral development in Primula into specific stages. Pin-form and thrum-form flowers are indistinguishable during early development with differentiation of the two floral morphs occurring beyond the differentiation of floral organs. Early ontogeny of flowers with homeotic mutant phenotypes was also studied to determine the timing of developmental reprogramming in these mutants. Phenotypes studied included Hose in Hose and Jack in the Green that develop petaloid sepals and leafy sepals, respectively, and Jackanapes plants that carry both these dominant mutations. Recessive double and semi-double flowers that produce additional whorls of petals and/or stamens in place of carpels were also studied. We describe a previously undocumented recessive Primula mutant phenotype, sepaloid, that produces sepals in place of petals and stamens, and a new non-homeotic, dominant mutant phenotype Split Perianth, in which sepals and petals fail to fuse to form the typical calyx and corolla structures. The molecular basis of these mutant phenotypes in relation to the ABC model is discussed.