Analysis of Arabidopsis PsbQ A Gene Expression in Transgenic Tobacco Reveals Differential Role of Its Promoter and Transcribed Region in Organ-specific and Light-mediated Regulation

Arabidopsis PsbQ, encoding a 16 kDa protein of the oxygen-evolving complex, is regulated by light and is expressed preferentially in leaf tissues. To analyze the components required for light-regulated and organ-specific expression of PsbQA, several promoter constructs were generated and expressed in tobacco. The 2.2 kb promoter could confer organ-specific expression of the reporter gene, whereas regulatory elements for light-dependent induction could not be located within this promoter and the transcribed region extending up to a second exon, represented by a genomic fragment encompassing the gene. The genomic fragment representing the transcribed region, however, could confer light regulation even on a constitutive promoter, as observed by steady-state mRNA analysis in T0 and T1 tobacco plants. The results obtained have led to the conclusion that regulatory elements for organ-specificity mainly reside in the promoter region whereas the transcribed region of the gene has an important role in light regulation.     

Expression of endogenous and microinjected hsp 30 genes in early Xenopus laevis embryos

In the present study, we have examined the regulation of expression of a newly isolated member of the hsp 30 gene family, hsp 30C. Using RT-PCR, we found that this gene was first heat-inducible at the tailbud stage of development. We also examined the expression of two microinjected modified hsp 30C gene constructs in Xenopus embryos. One of the constructs had 404 bp of hsp 30C 5′-flanking region, whereas the other had 3.6 kb. Both gene constructs had 1 kb of 3′-flanking region. RT-PCR assays were employed to detect the expression of these microinjected genes. The presence of extensive 5′- and 3′-flanking regions of the hsp 30C gene did not confer proper developmental regulation, since heat-inducible expression of both of the microinjected constructs was detectable at the midblastula stage. The premature expression of the microinjected hsp 30 gene was not a result of high plasmid copy number or the presence of plasmid DNA sequences. These results suggest that the microinjected genes contain all the cis-acting DNA sequences required for correct heat-inducible regulation but do not contain the elements required for the proper regulation of hsp 30 gene expression during development. It is possible that regulatory elements controlling the developmental expression of the hsp30 genes may reside upstream or downstream of the entire cluster. © 1993Wiley-Liss, Inc.     

De novo purine synthesis in Arabidopsis thaliana. II. The PUR7 gene encoding 5'-phosphoribosyl-4-(N-succinocarboxamide)-5-aminoimidazole synthetase is expressed in rapidly dividing tissues.

The small genome size and excellent genetics of Arabidopsis, as well as the ease with which it is transformed, make it a superb candidate for molecular genetic studies of the purine biosynthetic pathway. Herein we report the isolation, physical characterization, and dissection of the expression patterns of the single gene encoding 5'-phosphoribosyl-4-(N-succinocarboxamide)-5-aminoimidazole synthetase. This enzyme, encoded by the PUR7 gene, catalyzes aspartate addition at the alpha-amino group to the growing purine backbone. The expression of the PUR7 as directed by the 5' region, containing the promoter, mRNA leader, and leader intron, was examined in Arabidopsis using a transgenic reporter system. Our analysis demonstrates that the highest level of purine biosynthesis occurs in mitotically active tissues of the plant. Furthermore, purine biosynthesis appears to be under developmental and hormonal regulation. Inhibition of purine biosynthesis using substrate analogs results in arrested plant development and induction of purine gene expression. Purine nucleotides and their derivatives provide multiple cofactors for a variety of metabolic processes. Our findings begin to identify some of the regulatory mechanisms that affect the production of purine nucleotides in Arabidopsis and may give important insights into nitrogen metabolism in general.     

拟南芥FRUITFULL(FUL)基因的表达调控模式

FRUITFULL(FUL)基因是一类MADS box基因,在控制开花时间、花分生组织分化、茎生叶形态以及心皮和果实的发育中发挥重要作用。为了阐明FUL的表达调控模式,克隆了拟南芥Arabidopsis thaliana FUL启动子区(-2148bp~+96bp)及其第一内含子,并构建一系列启动子分段缺失表达载体及含FUL第一内含子的融合载体。并进一步构建了各顺式作用元件融合拟南芥TUBULIN和ACTIN启动子的表达载体。转基因拟南芥分析结果表明,FUL启动子的上游存在2个抑制其表达的顺式作用元件,其中一个很可能与转录因子AP1的结合有关;2个存在于上游调控区的CArG-box对FUL基因表达起到重要的调控作用;FUL基因第一内含子参与拟南芥心皮和雄蕊的发育调控,而且有增强基因表达的作用。     

A muscle-specific intron enhancer required for rescue of indirect flight muscle and jump muscle function regulates Drosophila tropomyosin I gene expression.

The control of expression of the Drosophila melanogaster tropomyosin I (TmI) gene has been investigated by P-element transformation and rescue of the flightless and jumpless TmI mutant strain, Ifm(3)3. To localize cis-acting DNA sequences that control TmI gene expression, Ifm(3)3 flies were transformed with P-element plasmids containing various deletions and rearrangements of the TmI gene. The effects of these mutations on TmI gene expression were studied by analyzing both the extent of rescue of the Ifm(3)3 mutant phenotypes and determining TmI RNA levels in the transformed flies by primer extension analysis. The results of our analysis indicate that a region located within intron 1 of the gene is necessary and sufficient for directing muscle-specific TmI expression in the adult fly. This intron region has characteristics of a muscle regulatory enhancer element that can function in conjunction with the heterologous nonmuscle hsp70 promoter to promote rescue of the mutant phenotypes and to direct expression of an hsp70-Escherichia coli lacZ reporter gene in adult muscle. The enhancer can be subdivided further into two domains of activity based on primer extension analysis of TmI mRNA levels and on the rescue of mutant phenotypes. One of the intron domains is required for expression in the indirect flight muscle of the adult. The function of the second domain is unknown, but it could regulate the level of expression or be required for expression in other muscle.     

Genes encoding a histone H3.3-like variant in Arabidopsis contain intervening sequences.

Two genes encoding a particular H3 histone variant were isolated from Arabidopsis thaliana. These genes differ from the H3 genes previously cloned from Arabidopsis and other plants by several interesting properties: (1) the two genes are located close to each other; (2) their coding regions are interrupted by two or three small introns, the two closest to the initiation codon being located at the same place in the two genes; (3) another, long intron is located in the 5'-untranslated region just before the initiation codon of gene I as deduced from the sequence of several corresponding cDNAs, and very likely also of gene II; (4) these genes do not show preferential expression in organs containing meristematic tissues contrary to the classical intronless replication-dependent histone genes, thus suggesting that their expression is not replication-dependent; (5) the protein encoded by both genes is the same and corresponds to a minor H3 variant highly conserved among all the plant species studied up to now. All these characteristics are common with the animal replication-independent H3.3 histone genes and it is assumed that the genes described here are the first example of the equivalent H3.3 gene family in plants. Interestingly, the promoter regions of the two genes have the same general structure as the Arabidopsis intronless genes. Possible implications on the regulation of H3 genes expression are discussed.     

Identification of both general and region-specific embryonic CNS enhancer elements in the nestin promoter

In this report, we investigate how nestin expression is controlled in neural progenitor cells of the embryonic CNS. A 374-bp region in the second intron of the human nestin gene is sufficient, and a 120-bp sequence in this region is required, to express the lacZ reporter gene throughout the developing CNS of E9.5-10.5 transgenic mouse embryos. The 120-bp element region contains putative binding sites for nuclear hormone receptors and we show that TRs, RXR, RAR, and COUP-TF bind to these motifs. A separate enhancer, located most probably 5' to the 120-bp sequence in the second intron, controls midbrain expression at E10.5. In conclusion, our data show that the nestin enhancer in the second intron contains elements both for general and for region-specific CNS progenitor cell expression and suggest that nuclear hormone receptors play a role in the regulation of nestin expression in the early CNS.     

Temporal and spatial regulation of DROOPING LEAF gene expression that promotes midrib formation in rice

Genes involved in the differentiation and development of tissues and organs are temporally and spatially regulated in plant development. The DROOPING LEAF (DL) gene, a member of the YABBY gene family, promotes midrib formation in the leaf and carpel specification in the flower. Consistent with these functions, DL is initially expressed in the central region of the leaf primordia (presumptive midrib) and in the presumptive carpel primordia in the meristem. To understand the regulatory mechanism underlying DL expression, we tried to identify cis-regulatory regions required for temporal and spatial expression of this gene. We found that the cis region responsible for the presumptive midrib-specific expression in the leaf primordia is located in intron 2. Next, we confined the region to a sequence of about 200bp, which corresponds to a conserved non-coding sequence (CNS) identified by phylogenetic footprinting. In addition, a sequence termed DG1, incorporating a 5' upstream region of about 7.4kb, and introns 1 and 2, was shown to be sufficient to induce DL in the presumptive midrib, and to suppress it in other regions in the leaf primordia. By contrast, the regulatory region required for carpel-specific expression was not included in the DG1 sequence. We modified Oryza sativa (rice) plant architecture by expressing an activated version of DL (DL-VP16) in a precise manner using the DG1 sequence: the resulting transgenic plant produced a midrib in the distal region of the leaf blade, where there is no midrib in wild type, and formed more upright leaves compared with the wild type.