Interstitial telomeric repeats within the Arabidopsis thaliana genome.

The sequence taAACCCTAa, or telo-box, is found at the same location within all known promoters of plant genes encoding the translation elongation factor EF-1 alpha. An analysis of Arabidopsis DNA sequences available in databases revealed that the sequence AAACCCTAA, corresponding to 1.3 units of the plant telomeric repeat AAACCCT, is over-represented within the Arabidopsis genome. These motifs are found both within the transcribed and the untranscribed genome. The examination of their location in the available sequences as well as in selected and partially sequenced cDNA clones suggest that they are preferentially located in the 5' region of genes. We show that a protein present in both maize and Arabidopsis cellular extracts is able to interact specifically with this motif. The putative functions associated with this sequence are discussed. We propose a model involving the telomerase to explain the spreading of this motif within the genome.

Characterization of an Arabidopsis thaliana gene that defines a new class of putative plant receptor kinases with an extracellular lectin-like domain.

We have characterized an Arabidopsis receptor-like serine/threonine kinase gene, Ath.lecRK1 (Arabidopsis thaliana lectin-receptor kinase), defining a new and putatively important class of plant receptor kinases. Structural features of the predicted polypeptide include an amino-terminal membrane-targeting signal sequence, a legume lectin-like extracellular domain, a single membrane-spanning domain, and a characteristic serine/threonine protein kinase domain. A recombinant protein containing the kinase domain can be autophosphorylated on a serine residue. Ath.lecRK1 is a member of a gene family of at least two closely related genes. Northern blot analysis indicates that the Ath.lecRK1 gene is weakly expressed in a variety of organs and is regulated in Arabidopsis cell suspension cultures according to the growth phase of cells. The role this new class of plant receptor kinase could play is discussed with regard to the transduction of oligosaccharide and plant hormone signals.

In synergy with various cis-acting elements, plant insterstitial telomere motifs regulate gene expression in Arabidopsis root meristems.

The telo-box, an interstitial telomere motif, was shown to regulate gene expression in root meristems, in synergy with a cis-acting element involved in the activation of expression of plant eEF1A genes, encoding the translation elongation factor EF1A, and of several ribosomal protein genes. We demonstrate here that the telo-box is also required for transcription activation by two other cis elements present within the promoter of genes encoding the acidic ribosomal protein rp40 and the proliferating cell nuclear antigen respectively. The control of gene expression by telo-boxes during cell cycle progression in Arabidopsis root meristems is discussed. A parallel is drawn with the function of telomeric sequences in Saccharomyces cerevisiae.

cDNA cloning and expression of an Arabidopsis GTP-binding protein of the ARF family.

A cDNA clone encoding a small GTP-binding protein, the ADP-ribosylation factor (ARF) was isolated from a cDNA library of Arabidopsis thaliana cultured cells. The predicted amino acid sequence was highly homologous to the known yeast, bovine and human ARF sequences. Southern analysis of Arabidopsis genomic DNA suggested the existence of at least two copies of ARF genes. The level of ARF mRNA was found to be nearly constant during all cell growth stages in suspension cultures.

A method for the elimination of false positives generated by the mRNA differential display technique.

The recently described mRNA differential display method provides an attractive tool for the isolation of genes showing regulated expression in a variety of systems. A key step in this technique consists of the isolation of PCR-synthesized radioactive cDNAs corresponding to differentially expressed mRNAs. Here, we show that the purified cDNAs remain contaminated with unrelated cDNA sequences that may lead to the artifactual isolation of false positives in the subsequent steps of the method. A powerful assay for the detection and elimination of this contaminating material, allowing the specific isolation of clones corresponding to the regulated genes identified by the differential display, is provided.

Pure yeast RNA polymerase B (II) initiates transcription at specific points on supercoiled yeast DNA.

Pure yeast RNA polmymerase B (II) can selectively initiate abortive transcription on a supercoiled recombinant plasmid DNA carrying yeast DNA in the presence of low concentrations of ribonucleoside triphosphates and Mn2+. Five major products ranging between 60 and 150 nucleotides were characterized by hybridization. Three of them originate from the vector pBR322 and two from the yeast DNA insert. Based on a RNA primer extension reaction with recombinant M13 DNAs as template, a method allowing the mapping of the short abortive RNA products has been developed. An initiation site within the yeast DNA insert has thus precisely been mapped. The DNA sequence in this region was determined and showed several relevant features. The in vitro initiation site is preceded by a potential TATATATA box at -40 base pairs and at -105 by the sequence GTTAATCT similar to the consensus sequence GCTCAATCT usually found around 80 base pairs upstream from the cap site. Large blocks of alternated purine pyrimidine residues are found in this region as for several known yeast promotors. The 5' end of the RNA initiated from this site contains several potential signals for the initiation of translation. The possibility that a B to Z transition of DNA could be important for the interaction of the RNA polymerase with its template is discussed.

Structural features of the DNA template required for transcription in vitro by yeast RNA polymerase B (II).

Yeast RNA polymerase II initiates in vitro transcription at two sites located within the vector DNA and the cloned promoter, on a recombinant plasmid DNA containing the yeast iso1 cytochrome c promoter. Both initiation sites are found within a DNA fragment hypersensitive to osmium tetroxide modification. Using a series of yeast iso1 cytochrome c promoter deletions, we have characterized an upstream DNA sequence required for optimal transcription from this site and shown in this case a correlation between osmium sensitivity and the capacity of RNA polymerase to initiate. However, perturbation of the double helix is not sufficient to generate a transcription initiation site. Insertion of 28 alternating AT residues at the EcoRV site of pBR322 generates an site hypersensitive to osmium tetroxide modification, that does not serve as a transcription start site.

Identification of proteins involved in the regulation of yeast iso- 1-cytochrome C expression by oxygen.

On the basis of a gel electrophoresis retardation assay, protein(s) which interact specifically with the upstream activating site (UASc) of the yeast iso-1-cytochrome C (CYC1) gene were identified and separated by heparin ultrogel chromatography. DNase I protection experiments indicate that these factors protect a 23-bp sequence overlapping the UASc site previously defined. The specific binding activity is strongly reduced in extracts prepared from a wild-type strain grown anaerobically. It is absent in a mutant strain blocked in the biosynthesis of heme but it is restored upon the addition of the missing precursor, delta amino levulinic acid (dALA) to the growth medium. In contrast, the binding activity does not differ significantly in extracts form a wild-type strain grown in either glucose or glycerol as carbon source. These data strongly argue that the CYC1 UAS binding protein(s) that we have identified mediate the oxygen and heme control of cytochrome C biosynthesis.

Yeast RNA polymerase II initiates transcription in vitro at TATA sequences proximal to potential non-B forms of the DNA template.

Pure yeast RNA polymerase II selectively initiates an abortive in vitro transcript within a TATA box of the yeast iso-1 cytochrome c gene promoter. Using a series of promoter deletions we show that a DNA sequence located upstream of the TATA box is needed for an efficient in vitro transcription. Supercoiling of the DNA template is an absolute requirement for the specific in vitro transcription. Examination of the DNA structure near several in vitro initiation sites shows that the common features observed are the presence of a TATA sequence in which RNA synthesis is initiated, and which is proximal to a potential non-B form of the DNA (a B to Z transition or a cruciform structure).

Denaturation map of polyoma DNA.

A denaturation map of polyoma DNA cleaved by Eco R1 to form linear molecules was established by electron microscopy. Partial denaturation, under the same conditions, of fragments obtained by Haemophilus influenzae restriction enzymes allowed us to align the denaturation map with the already established physical map of polyoma DNA (Griffin et al., 1974).

Endogenous nuclease activity in chick embryo lens cells.

The temporal and spatial sequence of nuclear disappearance during the terminal differentiation of lens fiber cells could be due to an impairment of the DNA repair pathways or to the appearance of an active DNA degradation process. The results presented here favor the second hypothesis. A single-stranded DNA nuclease activity and a double-stranded DNA nuclease activity have been found in chick embryo fiber cells. Moreover, there is a good correspondence between the variations of the nuclease activity and the stages of differentiation of the different samples analyzed.

In vitro transcription of the yeast alcohol dehydrogenase I gene by homologous RNA polymerase B (II). Selective initiation and discontinuous elongation on a supercoiled template.

A new in vitro approach is used to investigate the specificity of purified yeast RNA polymerase B (II). The template is supercoiled, the transcription is primed by a dinucleotide, and the transcripts are analyzed by polyacrylamide gel electrophoresis after synthesis in the absence of one nucleoside triphosphate. Under these conditions, two recombinant plasmids carrying the gene or part of the gene for yeast alcohol dehydrogenase I direct the synthesis of a very limited number of oligonucleotides. Elongation of these prelabeled oligomers, using unlabeled substrates, occurs in a discontinuous way. A major transcript of 200 nucleotides accumulates transiently. Southern hybridization shows that it is initiated about 1,400 bases upstream from the origin of the yeast alcohol dehydrogenase I gene. A minor start was identified, by a modified runoff experiment, at position -35 from the AUG initiation codon. The location of this site is related to the presumptive in vivo transcription starts. The selectivity disappears when the template is a truncated DNA. Then, initiation occurs predominantly at nicks introduced by the restriction enzymes.

Efficient and selective initiation by yeast RNA polymerase B in a dinucleotide-primed reaction.

Yeast RNA polymerase B catalyzes an efficient abortive initiation on double-stranded DNA templates using the appropriate combination of primer and substrate. The specificity of initiation was investigated using a recombinant plasmid (pJD14 DNA) containing the structural gene for yeast alcohol dehydrogenase I (ADHI). The combination of the dinucleotide UpA and UTP was 10 fold more efficient with pJD14 DNA than with the vector pBR322 DNA to direct the synthesis of the trinucleotide UpApU. Under these conditions, stable enzyme-DNA complexes were formed and could be retained on nitrocellulose filters. Using the UpA-primed system and a short pulse of RNA synthesis, transcription complexes were located on the yeast part of pJD14 DNA as evidenced by agarose gel electrophoresis. Southern hybridization of the pulsed RNA was restricted to a region, within the yeast DNA fragment, upstream to the initial region of the ADHI gene.

Native deoxyribonucleic acid transcription by yeast RNA polymerase--P37 complex.

The specific activity of yeast RNA polymerases A or B, when complexed with P37 cofactor, compares favorably with that of E. coli RNA polymerase. The stimulation is observed only with double-stranded DNA but does not result from DNase action. The Km for nucleotide substrates and the optimal conditions of transcription are not modified. P37 stimulates RNA synthesis by ternary transcription complexes in the presence of poly(rI) which prevents reinitiations. The RNA chain length, estimated by 5' end labeling or sedimentation, is increased in the presence of P37. On the other hand, the trinucleotide synthesis, which reflects the chain initiation reaction, is not affected. Therefore, the cofactor appears to act at the elongation step of RNA synthesis.

Characterization and properties of heteromeric plant protein complexes that interact with tef cis-acting elements in both RNA polymerase II-dependent promoters and rDNA spacer sequences.

The tef box, a cis-acting element identified in promoters of several plant genes encoding components of the translation apparatus, is involved in the activation of gene expression in cycling cells. In vitro, this element mediates the formation of two protein complexes called C1 and C2. A tef-like box is also found within the intergenic transcribed spacer of several plant rRNA genes. In radish this sequence has already been described as a protein-binding site putatively involved in the regulation of rDNA expression and is sufficient for formation of C1 complexes. By using mutated tef boxes, we show that tef-dependent activation of transcription is correlated with formation of both C1 and C2 complexes in a context-dependent manner. In transient expression experiments, the activation of a minimal promoter-GUS gene fusion is associated with the formation of C2 complexes. In contrast, the ability to form C1 complexes appears to allow activation of reporter gene expression in root meristems of transgenic Arabidopsis. SDS-PAGE analysis of purified protein fractions containing either the C1 or the C2 activity indicates a complex heteromeric structure for these potential regulators. Thus, the tef box seems to be a central component of the regulation of gene transcription in distinct and overlapping developmental programs, and could be involved in co-regulation of transcription by RNA polymerases I and II.

Lectin genes from the legume Medicago truncatula.

We report the cloning and characterization of two lectin genes from Medicago truncatula, designated Mtlec1 and Mtlec2. The two genes show a high degree of homology and apparently belong to a small multigene family. Mtlec1 appears to encode a functional lectin with 277 amino acids, whereas Mtlec2 is probably non-functional, since a frameshift mutation (insertion of two nucleotides) leads to premature translation termination after only 98 amino acids. The deduced amino acid sequence of the polypeptide MtLEC1 suggests that this lectin is a metalloprotein with Glc/Man specificity.