Differential expression profiles of growth-related genes in the elongation zone of maize primary roots

Growth in the apical elongation zone of plant roots is central to the development of functional root systems. Rates of root segmental elongation change from accelerating to decelerating as cell development proceeds from newly formed to fully elongated status. One of the primary variables regulating these changes in elongation rates is the extensibility of the elongating cell walls. To help decipher the complex molecular mechanisms involved in spatially variable root growth, we performed a gene identification study along primary root tips of maize (Zea mays) seedlings using suppression subtractive hybridization (SSH) and candidate gene approaches. Using SSH we isolated 150 non-redundant cDNA clones representing root growth-related genes (RGGs) that were preferentially expressed in the elongation zone. Differential expression patterns were revealed by Northern blot analysis for 41 of the identified genes and several candidate genes. Many of the genes have not been previously reported to be involved in root growth processes in maize. Genes were classified into groups based on the predicted function of the encoded proteins: cell wall metabolism, cytoskeleton, general metabolism, signaling and unknown. In-situ hybridization performed for two selected genes, confirmed the spatial distribution of expression shown by Northern blots and revealed subtle differences in tissue localization. Interestingly, spatial profiles of expression for some cell wall related genes appeared to correlate with the profile of accelerating root elongation and changed appropriately under growth-inhibitory water deficit.     

Three classes of proteinase inhibitor gene have distinct but overlapping patterns of expression in Pisum sativum plants

Genes representative of three gene classes encoding proteinase inhibitor proteins, with distinct spatial expression patterns, were isolated and characterized from Pisum.Under standard plant growth conditions, one class is expressed exclusively in seeds, whereas the other two make minor contributions to seed inhibitor proteins but are also expressed in other organs, predominantly in root endodermal and floral reproductive tissues. Two of the gene classes contain few genes and are genetically linked at the Tri locus, whereas the third class displays complex hybridization patterns to genomic DNA and maps to diverse genetic loci. Expression analysis of this last class suggests that only a small number of these genes are expressed. The quantitative effect of the Tri locus on root and floral inhibitor gene expression was examined in near-isogenic lines of pea. The proteins encoded by the three classes are all members of the same family (Bowman-Birk) of enzyme inhibitors but are distinct in terms of overall sequence, active site sequences and inhibitor function.     

Spatial patterns of gene expression in the extramatrical mycelium and mycorrhizal root tips formed by the ectomycorrhizal fungus Paxillus involutus in association with birch (Betula pendula) seedlings in soil microcosms

Functional compartmentation of the extramatrical mycelium of ectomycorrhizal (ECM) fungi is considered important for the operation of ECM associations, although the molecular basis is poorly characterized. Global gene expression profiles of mycelium colonizing an ammonium sulphate ((NH4)2SO4) nutrient patch, rhizomorphs and ECM root tips of the Betula pendula-Paxillus involutus association were compared by cDNA microarray analysis. The expression profiles of rhizomorphs and nutrient patch mycelium were similar to each other but distinctly different from that of mycorrhizal tips. Statistical analyses revealed 337 of 1075 fungal genes differentially regulated among these three tissues. Clusters of genes exhibiting distinct expression patterns within specific tissues were identified. Genes implicated in the glutamine synthetase/glutamate synthase (GS/GOGAT) and urea cycles, and the provision of carbon skeletons for ammonium assimilation via beta-oxidation and the glyoxylate cycle, were highly expressed in rhizomorph and nutrient patch mycelium. Genes implicated in vesicular transport, cytoskeleton organization and morphogenesis and protein degradation were also differentially expressed. Differential expression of genes among the extramatrical mycelium and mycorrhizal tips indicates functional specialization of tissues forming ECM associations.     

Genetic analysis and regulation of the Rhizobium meliloti genes controlling C4-dicarboxylic acid transport

The genes controlling the transport of C4-dicarboxylic acids from Rhizobium meliloti have been cloned and analysed. The nucleotide sequence of the control region of the structural dctA and the regulatory dctBD genes has been determined. Comparison with the Rhizobium leguminosarum dct genes revealed a high degree of homology. Gene fusions to the enteric lacZY reporter gene were constructed and the expression of the dctA and dctBD genes studied under various physiological conditions. In free-living cells, the regulatory dctBD genes are absolutely required for the expression of the dctA gene. In the root nodule environment, a dctA::lacZY gene fusion was found to be expressed in an R. meliloti strain mutated in both the dctB and dctD genes, but not in a strain mutated in the dctB gene alone. The presence of the conserved upstream NifA-binding sites on the dctA promoter sequence, coupled with the fact that the dctA::lacZY gene fusion is not expressed in root nodules formed by a nifA mutant strain of R. meliloti, supports the suggestion that NifA may be involved in the symbiotic expression of dctA in the absence of the regulatory dctBD genes. Under micro-aerobic conditions, however, NifA induction alone is not sufficient for expression of the dctA promoter, even though the NifA-dependent nifHDK promoter is highly expressed under these conditions.     

The promoter of the Vicia faba L. leghemoglobin gene VfLb29 is specifically activated in the infected cells of root nodules and in the arbuscule-containing cells of mycorrhizal roots from different legume and nonlegume plants

The VfLb29 leghemoglobin gene promoter was polymerase chain reaction-amplified from a Vicia faba genomic library and was fused to the gusAint coding region. Expression of the chimeric gene was analyzed in transgenic hairy roots of the legumes V. faba, V. hirsuta, and Medicago truncatula as well as in transgenic Nicotiana tabacum plants. The VfLb29 promoter was found to be specifically active not only in the infected cells of the nitrogen-fixing zone of root nodules but also in arbuscule-containing cells of transgenic V. faba and M. truncatula roots colonized by the endomycorrhizal fungus Glomus intraradices. In addition to these two legumes, specific expression in arbuscule-containing cells was also observed in the nonlegume N. tabacum. All studies were done in comparison to the V. faba leghemoglobin gene promoter VfLb3 that as VfLb29 was expressed in the infected cells of root nodules but showed no activity in endomycorrhiza. An activation of the VfLb29 promoter due to hypoxia in metabolically active tissues was excluded. The conserved activation in arbuscule-containing cells of legumes and the nonlegume N. tabacum suggests a conserved trigger for this promoter in legume and nonlegume endomycorrhiza symbioses.     

Quantitative evolutionary genomics: differential gene expression and male reproductive success in Drosophila melanogaster

We combined traditional quantitative genetics and oligonucleotide microarrays to examine within-population genetic variation in a trait closely related to fitness. The trait, male reproductive success under competitive conditions (MCRS), is of central importance to both life-history and sexual-selection theory. We identified 27 candidate genes whose expression levels were associated with within-population variation in MCRS. "High" MCRS was associated with low expression of a cytochrome P450 that causes pesticide resistance, suggesting a fitness cost to resistance. Two groups of metabolic proteins (glutathione transferases and phosphatases) were significantly over-represented, and a large portion of the candidates are genes involved in oxidative stress resistance, energy acquisition or energy storage. Genes expressed in accessory glands and testes were not over-represented among differentially expressed genes, but testis-expressed genes were significantly more likely to be upregulated in high MCRS genotypes. Finally, nine candidate genes that we identified had no previous functional annotation, and this experiment suggests that they play a role in male reproductive success.     

利用cDNA-AFLP技术分析旱作促进水稻种子根伸长过程中的基因表达

短期旱作促进水稻种子根的伸长。利用cDNA—AFLP技术分析种子根根尖在旱作条件下差异表达的基因,同时比较这些基因在种子根尖、侧根和不定根原基区的表达差异。在1640个片段中,70个在种子根根尖中受旱作诱导,其中24个被克隆并测序。2个基因分别编码丙酮酸脱氢酶激酶(PDK)和腺嘌吟转磷酸核糖基酶(APRT),并用电子拼接技术获得水稻的APRT全长cDNA;另一个经cDNA末端快速扩增法延长后仍无同源序列。Northern杂交验证了这3个基因的cDNA—AFLP表达谱。这是首次报告使用cDNA—AFLP技术研究水稻根组织的差异表达基因。     

Selection of housekeeping genes for qRT-PCR analysis in potato tubers under cold stress

Quantitative real-time polymerase chain reaction (qRT-PCR) is currently the most sensitive method used for quantitative gene expression studies. However, minimal variation in the amount of material and presence of inhibitors affecting enzyme efficiency can lead to significant quantification errors. Accurate data normalization is vital using reference genes as internal controls. Many so-called housekeeping genes or reference genes with assumed stable expression can exhibit either up- or downregulation depending on the developmental stage or other environmental conditions. We have evaluated six reference genes (actin, APRT, 18S rRNA, ef1α, β-tubulin and ribosomal protein L2) for qRT-PCR profiling experiments in potato tuber tissues of five varieties during cold storage at different temperatures and treatment periods. Genes were ranked according to their expression stability by BestKeeper, geNorm and NormFinder software tools in the same order. This means that any of them can be used for this purpose. The results indicated that ef1α and APRT were the most stably expressed genes in the potato tuber tissues under different cold storage regimes. We therefore recommend use of this pair of genes as internal controls for gene expression studies under the described conditions.