M Van Montagu

cdc2a expression in Arabidopsis is linked with competence for cell division.

A key regulator of the cell cycle is a highly conserved protein kinase whose catalytic subunit, p34(cdc2), is encoded by the cdc2 gene. We studied the control of the expression of the Arabidopsis cdc2a gene in cell suspensions and during plant development. In cell cultures, arrest of the cell cycle did not significantly affect cdc2a mRNA levels, but nutrient conditions were important for cdc2a expression. During plant development, the pattern of cdc2a expression was strongly correlated with the cell proliferation potential. The effects of external signals on cdc2a expression were analyzed. Wounding induced expression in leaves. Lack of light altered temporal regulation of cdc2a in the apical but not root meristem of seedlings. Differential cdc2a responses were obtained after different hormone treatments. Signals present only in intact plants were necessary to mediate these responses. Although other control levels have yet to be analyzed, these results suggest that the regulation of cdc2a expression may contribute greatly to spatial and temporal regulation of cell division in plants. Our results also show that cdc2a expression is not always coupled with cell proliferation but always precedes it. We propose that cdc2a expression may reflect a state of competence to divide, and that the release of other controls is necessary for cell division to occur.

Plant enolase: gene structure, expression, and evolution.

Enolase genes were cloned from tomato and Arabidopsis. Comparison of their primary structures with other enolases revealed a remarkable degree of conservation, except for the presence of an insertion of 5 amino acids unique to plant enolases. Expression of the enolase genes was studied under various conditions. Under normal growth conditions, steady-state messenger and enzyme activity levels were significantly higher in roots than in green tissue. Large inductions of mRNA, accompanied by a moderate increase in enzyme activity, were obtained by an artificial ripening treatment in tomato fruits. However, there was little effect of anaerobiosis on the abundance of enolase messenger. In heat shock conditions, no induction of enolase mRNA was observed. We also present evidence that, at least in Arabidopsis, the hypothesis that there exists a complete set of glycolytic enzymes in the chloroplast is not valid, and we propose instead the occurrence of a substrate shuttle in Arabidopsis chloroplasts for termination of the glycolytic cycle.

Differential expression of five Arabidopsis genes encoding glycine-rich proteins.

Five cDNA clones coding for glycine-rich proteins in Arabidopsis thaliana were isolated. The corresponding genes are present in the genome as single copies. The derived protein sequences contain highly repetitive glycine-rich motifs. There is, however, little homology among them, nor with previously described glycine-rich proteins from other species. All five genes are expressed in leaves and stems of 6-week-old plants but show different patterns of expression in other organ systems. Analysis of the effect of different external stimuli on the expression pattern showed that, in most cases, the transcript levels were moderately but selectively affected. With flooding stress, the accumulated level of the transcript from one of the genes was remarkably increased.

Differential Expression of the Arabidopsis 2S Albumin Genes and the Effect of Increasing Gene Family Size.

We studied the expression of the four genes encoding 2S albumin seed storage proteins (at2S1 to at2S4) in Arabidopsis thaliana. All four genes followed similar temporal profiles throughout development, but at2S2 and at2S3 were expressed at significantly higher levels than at2S1 or at2S4. In situ hybridization showed that at2S2 to at2S4 mRNAs were present throughout the embryo, whereas at2S1 was expressed at levels similar to at2S2 and at2S3 in the embryo axis but at only insignificant levels in the cotyledons. The different members of the gene family are, thus, likely to be regulated by different combinations of cis-acting elements, but it cannot be ruled out that post-transcriptional factors play a role. We studied the effect of enlarging the gene family by introducing an extra, nearly identical gene driven by the promoter of at2S1. The data were consistent with a model in which the expression of at2S2 to at2S4 is not affected by that of at2S1, and in which, at least at low copy numbers of the introduced gene, there is no limit on the overall amount of RNA that the at2S gene family can produce.

The 3' untranslated region of satellite tobacco necrosis virus RNA stimulates translation in vitro.

The RNA of satellite tobacco necrosis virus (STNV) is a monocistronic messenger that lacks both a 5 cap structure and a 3 poly(A) tail. We show that in a cell-free translation system derived from wheat germ, STNV RNA lacking the 600-nucleotide trailer is translated an order of magnitude less efficiently than full-size RNA. Deletion analyses positioned the translational enhancer domain (TED) within a conserved hairpin structure immediately downstream from the coat protein cistron. TED enhances translation when fused to a heterologous mRNA, but the level of enhancement depends on the nature of the 5 untranslated sequence and is maximal in combination with the STNV leader. The STNV leader and TED have two regions of complementarity. One of the complementary regions in TED resembles picornavirus box A, which is involved in cap-independent translation but which is located upstream of the coding region.

Induction Patterns of an Extensin Gene in Tobacco upon Nematode Infection.

When sedentary endoparasitic nematodes infect plants, they induce complex feeding sites within the root tissues of their host. To characterize cell wall changes induced within these structures at a molecular level, we studied the expression of an extensin gene (coding for a major structural cell wall protein) in nematode-infected tobacco roots. Extensin gene expression was observed to be induced very early upon infection. This induction was weak, transient, and probably due to wounding during penetration and migration of the tobacco cyst nematode Globodera tabacum ssp solanacea-rum. In contrast, high extensin gene expression was observed during the whole second larval stage (an ~2-week-long phase of establishment of the feeding site) of the root knot nematode Meloidogyne javanica. During later stages of this interaction, expression gradually decreased. Extensin gene expression was found in at least three different tissues of the gall. We propose that distinct mechanisms lead to induced expression in these different cell types. The significance of these results for the understanding of plant-nematode interactions as well as the function of structural cell wall proteins, such as extensin, is discussed.

rha1, a gene encoding a small GTP binding protein from Arabidopsis, is expressed primarily in developing guard cells.

The rha1 gene from Arabidopsis encodes a small GTP binding protein belonging to the Ypt/Rab family. Transgenic Arabidopsis plants containing the promoter region of the rha1 gene fused to the beta-glucuronidase (gus) reporter gene revealed gus expression limited mainly to the guard cells of stomata, the stipules, and the root tip of young plants. In flowering plants, expression was found predominantly in the receptacle and in guard cells of the different flower organs. High GUS activity could also be seen in callus tissue and developing seeds. No detectable activity was present in other plant tissues; activity could not be induced by various treatments. GUS activity was visualized histochemically using both 5-bromo-4-chloro-3-indolyl beta-D-glucuronide and a newly developed GUS substrate: Sudan II-beta-glucuronide. The latter precipitates as red crystals at the site of GUS activity. Results obtained by the gus analysis were confirmed by whole-mount mRNA in situ hybridization. A hypothesis for the function of the Rha1 protein is discussed.

Insertional mutagenesis in Arabidopsis thaliana

Abstract Recently, a number of mutant gene loci in the Arabidopsis thaliana plant genome have been identified through insertional mutagenesis. In this review, we evaluate different methods used for Agrobacterium tumefaciens -mediated T-DNA insertional mutagenesis with regard to their mutation frequencies and conclude that a major breakthrough in the isolation of genes involved in plant development has been acheived. To provide a specific example, we summarize recent progress made in the understanding of flower morphogenesis at the molecular level through the study of homeotic genes obtained via gene tagging. T-DNA gene fusion vectors are being discussed that will allow the isolation of plant regulatory sequences with particular cell or tissue specificity, or that are controlled by specific external stimuli. Finally, we report on the approaches followed to convert the maize transposons Ac/Ds into valuable gene tags for use in a heterologous host such as Arabidopsis .

Studies on the bacteriophage MS2: XLI. Nature of the azure mutation

Abstract Azure (or reverse amber) mutants grow normally on wild-type Escherichia coli but not on host strains harbouring a strong UAG suppressor mutation. Three different bacteriophage MS2 azure mutants obtained by treatment with nitrous acid have been characterized at the nucleotide sequence level. The 3′-end fragment of the 32 P-labelled mutant genomes was isolated by DNA:RNA hybridization and treatment with nuclease S 1 , and was analyzed by mini-fingerprinting of the RNA. It is known that the wild-type MS2 polymerase gene ends with a UAG codon, followed seven triplets further by an in-phase UAA triplet. All three azure mutants contained an A → G transition in this UAA second stop codon of the polymerase gene, resulting in a second suppressible UAG (amber) codon. Analysis of revertants demonstrated that the azure mutation can be counteracted either by a true site reversion at the second stop or by the creation of a new stop signal for the polymerase gene, either UAA (ochre) or UGA (opal), before or at the first stop, or beyond the second stop. On the basis of these results, a mechanism for the azure mutation is proposed. Silent mutations (one in the coding region, three in the untranslated 3′-terminal sequence) have also been observed in these phage stocks.