José A. Martínez-Izquierdo

Natural selection and climate change: temperature‐linked spatial and temporal trends in gene frequency in Fagus sylvatica

Rapid increases in global temperature are likely to impose strong directional selection on many plant populations, which must therefore adapt if they are to survive. Within populations, microgeographic genetic differentiation of individuals with respect to climate suggests that some populations may adapt to changing temperatures in the short‐term through rapid changes in gene frequency. We used a genome scan to identify temperature‐related adaptive differentiation of individuals of the tree species Fagus sylvatica. By combining molecular marker and dendrochronological data we assessed spatial and temporal variation in gene frequency at the locus identified as being under selection. We show that gene frequency at this locus varies predictably with temperature. The probability of the presence of the dominant marker allele shows a declining trend over the latter half of the 20th century, in parallel with rising temperatures in the region. Our results show that F. sylvatica populations may show some capacity for an in situ adaptive response to climate change. However as reported ongoing distributional changes demonstrate, this response is not enough to allow all populations of this species to persist in all of their current locations.

Subcellular localization of glutelin-2 in maize (Zea mays L.) endosperm.

Accumulation of the 28 KD protein of the glutelin-(G2) fraction was followed in developing maize endosperm, using sodium dodecylsulphate polyacrylamide gel electrophoresis (SDS-PAGE) and peak integration of scanned gels. 28 KD glutelin-2 could already be observed from 15 days after pollination and its accumulates reached a plateau during the second half of the development period. The process of biosynthesis of 28 KD glutelin-2 and zeins occurs in a parallel way. Subcellular fractions obtained from linear sucrose gradient centrifugation of developing maize endosperms were analyzed by SDS-PAGE and immunoblotting using a serum reacting against glutelin-2 and 14 KD Z2. Glutelin-2 was found to be present in the protein bodies when subcellular fractionation was carried out without dithiothreitol (DTT). The presence of a reducing agent causes the elution of glutelin-2 from protein bodies. Immunocytochemical labelling using the protein A-colloidal gold technique in protein bodies incubated with anti-G2 IgG revealed that G2 is located mainly in the periphery of protein bodies. These results are interpreted as indicating a structural role for glutelins in protein bodies.

Induction of mRNA accumulation corresponding to a gene encoding a cell wall hydroxyproline-rich glycoprotein by fungal elicitors.

The Hrgp (hydroxyproline-rich glycoprotein) gene codes in maize for one of the most abundant proteins of the cell wall. HRGPs may contribute to the structural support of the wall and they have also been involved in plant defense mechanisms. This second aspect has been tested for the Hrgp gene in maize where, in contrast with the situation in dicot species, the gene is encoded by a single-copy sequence. Hrgp mRNA accumulation is induced in maize suspension-cultured cells by elicitors, isolated either from maize pathogenic or non-pathogenic fungi. The induction of Hrgp mRNA accumulation by elicitor extracted from Fusarium moniliforme has been studied in detail. The level of induction depends on elicitor concentration and remains high until at least 24 h. Ethylene and protein phosphorylation appear to be involved in the transduction pathway of Hrgp gene activation by the F. moniliforme elicitor but not by 5 µM methyl jasmonate or 1 mM salycilic acid. Different compounds known to participate in plant stress responses such as ascorbic acid or reduced glutathione have also a positive effect on Hrgp mRNA accumulation.

Characterization of a gene encoding an abscisic acid-inducible type-2 lipid transfer protein from rice.

The cloning and sequence analysis of a novel gene that encodes a type 2 non‐specific lipid transfer‐like protein (LTP) from rice is reported. Sequence analysis revealed an ORF encoding a protein showing characteristics of the LTP proteins. However, rice LTP2 is more similar to heterologous LTPs than to rice LTP1, supporting the existence of two distinct families of plant LTPs. Ltp2 mRNA is accumulated only in mature seeds. In vegetative tissues, mRNA was only detected after treatment with abscisic acid (ABA), mannitol or NaCl. Transient expression experiments that the 61 nucleotides upstream of the TATA box, containing two ACGT boxes and the motif I, are sufficient for ABA responsiveness of the Ltp gene.

CIRE1, a novel transcriptionally active Ty1-copia retrotransposon from Citrus sinensis.

LTR retrotransposons (LTR-RTNs) are widespread constituents of eukaryote genomes, particularly plant genomes. Although LTR-RTNs from plants were thought to be transcriptionally silent in somatic tissues, evidences of activity under certain conditions are available for some of them. In order to investigate LTR-RTNs in the Citrus sinensis genome, we analysed them by PCR using degenerate primers corresponding to highly conserved domains. All elements of the two types of LTR-RTN comprise about 23% of the genome, the copia group contribution being higher (13%) than the gypsy one (10%). From dendogram analysis, we report seven new copia RTN families, named CIRE1 to CIRE7. Here, we report on the first complete retrotransposon identified in Citrus (named CIRE1), which has all the features of a typical copia RTN. CIRE1 retrotransposon has around 2,200 full-length copies, contributing to 2.9% of the C. sinensis genome. CIRE1 has a root-specific expression in sweet orange plants. We have also determined that wounding and exogenous application of plant hormones, as methyl jasmonate and auxin, increase the transcription level of CIRE1 in leaf tissues. In addition, we show that CIRE1 5′LTR promoter can drive transient expression of the gus reporter gene in heterologous plant systems. These findings confirm CIRE1 as one of the few transcriptionally active RTNs described in plants and to our knowledge the first one to be reported in Citrus species.

Regulation of the maize HRGP gene expression by ethylene and wounding, mRNA accumulation and qualitative expression analysis of the promoter by microprojectile bombardment

The expression of the maize gene coding for a hydroxyproline-rich glycoprotein (HRGP) has been studied by measuring the mRNA accumulation after wounding or ethylene treatment. RNA blot and in situ hybridization techniques have been used. The temporal and tissue-specific expression has been observed: the cells related to the vascular system show the more intense HRGP mRNA accumulation. Transcriptional constructions of the maize HRGP promoter have been tested on different maize tissues by microbombarding. A 582 bp promoter is able to direct the expression of the gus gene on calli and young leaves. Constructions having shorter promoter sequences lose this ability. The 582 bp construction retains the general specificity of expression observed for the HRGP gene.

What makes Grande1 retrotransposon different

Grande1 elements constitute a family of Ty3 retrotransposons present in the Zea genus in more than 1000 copies in Zea diploperennis and maize. The sequences of three Grande1 flanking regions, two from Z. diploperennis and one from maize, reveal transposable elements as insertion targets, suggesting a preferential integration of Grande1 elements into other transposable elements. These retrotransposons are remarkable for their large size of around 14 kb, which is a consequence of a very large 3′ region of more than 7 kb. Atypical entities within this region are two arrays of unrelated tandem repeats with potential stable stem-loop structures. A large portion of the same region is occupied by ORFs, although only ORF23, whose function is unknown, is presumably transcribed in antisense orientation to the reverse transcriptase ORF. Only ORF23 has a codon usage similar to the one tabulated for highly-expressed maize genes. Correspondingly, the transcript of 900 b that hybridizes with ORF23 probes is found in all the maize tissues explored. This is despite the high level of methylation in the DNA of Grande1. Genomic RNA has not been detected in any tissue or situation studied, probably reflecting a non-functional retrotransposon. The origin of ORF23 and the remainder 3′ region might be due to a transduction event.

Different mechanisms generating sequence variability are revealed in distinct regions of the hydroxyproline-rich glycoprotein gene from maize and related species

SummaryThe sequences of the genes coding for a hydroxyproline-rich glycoprotein from two varieties of maize (Zea mays, Ac1503 and W22), a teosinte (Zea diploperennis) and sorghum (Sorghum vulgare) have been obtained and compared. Distinct patterns of variability have been observed along their sequences. The 500 by region immediately upstream of the TATA box is highly conserved in theZea species and contains stretches of sequences also found in the sorghum gene. Further upstream, significant rearrangements are observed, even between the two maize varieties. These observations allow definition of a 5′ region, which is common to the four genes and is probably essential for their expression. The 3′ end shows variability, mostly due to small duplications and single nucleotide substitutions. There is an intron present in this region showing a high degree of sequence conservation among the four genes analyzed. The coding region is the most divergent, but variability arises from duplications of fragments coding for similar protein blocks and from single nucleotide substitutions. These results indicate that a number of distinct mechanisms (probably point mutation, transposon insertion and excision, homologous recombination and unequal crossing-over) are active in the production of sequence variability in maize and related species. They are revealed in different parts of the gene, probably as the result of the different types of functional constraints acting on them, and of the specific nature of the sequence in each region.

Characterization of a barley gene coding for an α-amylase inhibitor subunit (CMd protein) and analysis of its promoter in transgenic tobacco plants and in maize kernels by microprojectile bombardment

A gene coding for a barley CMd protein was isolated from a genomic library using a cDNA probe encoding the wheat CM3 protein. Promoter sequence analysis reveals motifs found in genes specifically expressed in endosperm and aleurone cells, as well as TATA and other putative functional boxes. 720 bp of the Hv85.1 CMd protein gene promoter, when fused to a gus coding region, were unable to direct GUS activity in the seeds of transgenic tobacco plants. In contrast, the same construction delivered into immature maize kernels by microprojectile bombardment was able to direct expression of GUS in the outermost cell layers of maize endosperm in both a tissue-specific and a developmentally determined manner.

Chromosome localization and characterization of a family of long interspersed repetitive DNA elements from the genus Zea

This paper describes the characterization and chromosomal distribution of new long repetitive sequences present in all species of the genus Zea. These sequences constitute a family of moderately repetitive elements ranging approximately from 1350 to 1700 copies per haploid genome in modern maize (Zea mays ssp. mays) and teosinte (Zea diploperennis), respectively. The elements are long, probably larger than 9 kb, and they show a highly conserved internal organization among Zea subspecies and species. The elements are present in all maize chromosomes in an interspersed pattern of distribution, are absent from centromeric and pericentric heterochromatin, and with some clustering in the distal regions of chromosome arms.