The expression of D-cyclin genes defines distinct developmental zones in snapdragon apical meristems and is locally regulated by the Cycloidea gene.

Three D-cyclin genes are expressed in the apical meristems of snapdragon (Antirrhinum majus). The cyclin D1 and D3b genes are expressed throughout meristems, whereas cyclin D3a is restricted to the peripheral region of the meristem, especially the organ primordia. During floral development, cyclin D3b expression is: (a) locally modulated in the cells immediately surrounding the base of organ primordia, defining a zone between lateral organs that may act as a developmental boundary; (b) locally modulated in the ventral petals during petal folding; and (c) is specifically repressed in the dorsal stamen by the cycloidea gene. Expression of both cyclin D3 genes is reduced prior to the cessation of cell cycle activity, as judged by histone H4 expression. Expression of all three D-cyclin genes is modulated by factors that regulate plant growth, particularly sucrose and cytokinin. These observations may provide a molecular basis for understanding the local regulation of cell proliferation during plant growth and development.

The Arabidopsis Cdc2a-interacting protein ICK2 is structurally related to ICK1 and is a potent inhibitor of cyclin-dependent kinase activity in vitro.

Cyclin-dependent kinases (CDKs) are important regulators of the eukaryotic cell division cycle. To study protein-protein interactions involving plant CDKs, the Arabidopsis thaliana Cdc2aAt was used as bait in the yeast two-hybrid system. Here we report on the isolation of ICK2, and show that it interacts with Cdc2aAt, but not with a second CDK from Arabidopsis, Cdc2bAt. ICK2 contains a carboxy-terminal domain related to that of ICK1, a previously described CDK inhibitor from Arabidopsis, and to the CDK-binding domain of the mammalian inhibitor p27Kip1. Outside of this domain, ICK2 is distinct from ICK1, p27Kip1, and other proteins. At nanogram levels (8 nM), purified recombinant ICK2 inhibits p13Suc1-associated histone H1 kinase activity from Arabidopsis tissue extracts, demonstrating that it is a potent inhibitor of plant CDK activity in vitro. ICK2 mRNA was present in all tissues analysed by Northern hybridization, and its distribution was distinct from that of ICK1. These results demonstrate that plants possess a family of differentially regulated CDK inhibitors that contain a conserved carboxy terminal but with distinct amino terminal regions.

The Arabidopsis NPR1/NIM1 protein enhances the DNA binding activity of a subgroup of the TGA family of bZIP transcription factors.

The Arabidopsis NPR1 gene is essential in activating systemic, inducible plant defense responses. To gain a better understanding of NPR1 function, we conducted a yeast two-hybrid screening procedure and identified a differential interaction between NPR1 and all known members of the Arabidopsis TGA family of basic leucine zipper transcription factors. In the electrophoretic mobility shift assay, NPR1 substantially increased the binding of TGA2 to its cognate promoter element (as-1) as well as to a positive salicylic acid-inducible element (LS7) and a negative element (LS5) in the promoter of the pathogenesis-related PR-1 gene. Proteins encoded by npr1 mutants interacted poorly with TGA2 and did not substantially increase TGA2 binding to the as-1, LS5, or LS7 elements, thus establishing a link between the loss of disease resistance and the loss of TGA2 interaction and NPR1-enhanced DNA binding. Coupled with observations that the DNA binding activity of TGA factors is deregulated in npr1 plants, the results suggest that NPR1-mediated DNA binding of TGA2 is critical for activation of defense genes.

A tobacco cryptic constitutive promoter, tCUP, revealed by T-DNA tagging.

We have isolated a constitutive promoter sequence, tCUP, from tobacco by T-DNA tagging using a promoterless GUS-nos3' reporter gene construct. The T-DNA integration event produced a translational fusion with the GUS gene that is expressed widely in organs, at both the mRNA and enzyme activity levels. In tobacco transformed with a tCUP-GUS-nos3' gene, GUS specific activity in leaves was within a range of values similar to those of plants transformed with the widely used constitutive promoter gene fusion, CaMV 35S promoter-GUS-nos3'. Characteristics of the tCUP promoter sequence differ from those of other plant constitutive promoters; for instance, the tCUP sequence lacks a TATA box. Transcription initiates at a single site within the tCUP sequence which is similar to a transcriptional start site consensus sequence determined for plant genes. The tCUP promoter is cryptic as RNA accumulation at the transcriptional start site is not detected in untransformed tobacco. Thus, tCUP is the first example of a cryptic, constitutive promoter isolated from plants. The tCUP-GUS-nos3' gene fusion produced GUS activity in tissues of all species tested suggesting that tCUP may utilize fundamental transcription mechanisms found in plants.

Distinct classes of cdc2-related genes are differentially expressed during the cell division cycle in plants.

cdc2 and several related genes encode the catalytic subunits of cyclin-dependent kinases, which have been implicated in a number of cellular processes, including control of cell division. As a first step in exploring their function in plants, we isolated four cdc2-related genes from Antirrhinum. Two genes, cdc2a and cdc2b, encode proteins that contain a perfectly conserved PSTAIRE motif characteristic of cdc2 homologs, whereas the products of the two remaining genes, cdc2c and cdc2d, appear to represent a new subclass of proteins that have so far only been identified in plants. Transcripts of these novel genes were localized in isolated cells dispersed throughout actively dividing regions of the inflorescence. This localization is consistent with accumulation that is specific to particular phases of the cell cycle. Correlating cell labeling with nuclear condensation and double-labeling experiments using cdc2 and histone H4 as probes indicated that cdc2c transcripts accumulate during S phase as well as during the G2 and M transition, whereas cdc2d expression was specific to the G2 and M phases. All cells labeled with cdc2d also contained cdc2c label, Indicating that expression of cdc2d completely overlapped with that of cdc2c. Transcripts of cdc2a and cdc2b were detected in all cells within actively dividing regions, but at levels that were only slightly higher than those observed in nondividing areas. These transcripts did not appear to accumulate in a cell cycle-specific fashion. The genes cdc2a and cdc2b were able to partially complement a yeast cdc2 mutation, although all four genes appeared to interfere with the sizing mechanism of yeast cells. We propose that plants contain at least two classes of cdc2-related genes that differ in structure, expression, and perhaps function.

T-DNA tagging of a seed coat-specific cryptic promoter in tobacco.

T-DNA tagging with a promoterless beta-glucuronidase (GUS) gene generated a transgenic Nicotiana tabacum plant that expressed GUS activity only in developing seed coats. Cloning and deletion analysis of the GUS fusion revealed that the promoter responsible for seed coat specificity was located in the plant DNA proximal to the GUS gene. A 3.3 kb fragment corresponding to the insertion site was isolated from untransformed plants. No long open reading frames were detected in this region. Northern blots and RNase protection assays failed to detect transcripts from this region in untransformed plants. Furthermore, the insertion site was situated within the N. tomentosiformis genome of the allotetraploid species N. tabacum, in a region which is not conserved within the genus Nicotiana. It is concluded that seed coat-specific GUS expression in this transgenic plant resulted from T-DNA insertion next to a cryptic promoter. These results suggest that at least some of the fusions generated to marker genes in promoter trapping studies are not associated with conventional gene promoters. The possibility that similar insertion events play a role in gene evolution is discussed.

Patterns of cell division revealed by transcriptional regulation of genes during the cell cycle in plants.

Transcripts from five cell cycle related genes accumulate in isolated cells dispersed throughout the actively dividing regions of plant meristems. We propose that this pattern reflects gene expression during particular phases of the cell division cycle. The high proportion of isolated cells suggests that synchrony between daughter cells is rapidly lost following mitosis. This is the first time that such a cell specific expression pattern has been described in a higher organism. Counterstaining with a DNA specific dye revealed that transcripts from three genes (two mitotic cyclins and a cdc2-like gene) accumulate during part of interphase and early mitosis whereas transcripts from a histone H4 gene are preferentially detected only in interphase cells. Double labelling for cyclin and histone H4 transcripts confirms that these genes are expressed in different cells, and therefore at different phases of the cell cycle. The results suggest that transcriptional regulation of cell cycle related genes may be important in controlling cell division in plants, and that these genes are useful markers for identifying cells at specific phases of the cell cycle within plant meristems.

Detection of gene regulatory signals in plants revealed by T-DNA-mediated fusions.

A binary vector, pPRF120, was designed to detect T-DNA insertions within transcriptionally active areas of the plant genome. Linked to the right-border repeat, the vector contains a promoterless beta-glucuronidase (GUS) gene which can, upon integration into chromosomes, be activated by cis-acting regulatory elements. The vector also incorporates a chimeric marker gene conferring resistance to kanamycin to ensure recovery of gene fusions regardless of the extent of their tissue-specific or developmentally regulated expression, and to permit analysis of the frequency of plants which express the promoterless reporter. Approximately 1000 transgenic tobacco plants harboring pPRF120 were regenerated. Analysis of 52 individuals indicated that more than 80% contain single, intact copies of the T-DNA, regardless of their ability to express the promoterless GUS gene. Screening of leaf tissue from the 1000 pPRF120 transformants revealed that ca. 5% of the plants contained GUS activity. Fluorogenic and histological GUS assays were used to visualize and quantify tissue- and cell-specific gene expression. The potential usefulness of pPRF120 in comparison to other vectors designed to generate in vivo gene fusions is discussed.

Procedure for Obtaining Efficient Root Nodulation of a Pea Cultivar by a Desired Rhizobium Strain and Preempting Nodulation by Other Strains.

The specificity between the sym-2 gene bred into certain cultivars of pea (Pisum sativum L.) and the nodX gene, present only rarely in isolates of Rhizobium leguminosarum, can be exploited to preempt competition or nodulation blocking by a Rhizobium strain indigenous to a soil environment. The principle is to isolate an R. leguminosarum strain prevalent in a locale, convert it into a strain that will nodulate a desirable pea cultivar carrying sym-2 by establishing nodX in it, and then use the resulting Rhizobium strain with the pea cultivar carrying sym-2. To accomplish this, we first constructed a transposon Tn5 derivative called Tn5nodX and an efficient delivery vehicle that is suicidal in R. leguminosarum. We tested the potential utility of the system in greenhouse experiments. The results are encouraging enough to warrant extensive experiments under field conditions.

Mutations within the replicon of the IncN plasmid pCU1 that affect its Escherichia coli polA-independence but not its autonomous replication ability.

The minimal replicon of the incompatibility N group plasmid pCU1 is contained within a 2-kb DNA region of the plasmid. The ability of this region and of the deletion derivatives thereof, that are capable of autonomous maintenance, to direct polypeptide synthesis was examined. Two proteins of 27 and 5.5 kDa are encoded by the minimal replicon. Polypeptide chain-terminating mutations within the predicted open reading frame for the 27-kDa polypeptide abolished the synthesis of this polypeptide and also the Escherichia coli polA-independence phenotype of the pCU1 replicon. However, these mutations did not affect the autonomous replication ability of the pCU1 replicon in wild-type E. coli and the expression of incompatibility towards the parental plasmid.