Tracking of the CaMV-35S promoter performance in GFP transgenic tobacco, with a special emphasis on flowers and reproductive organs, confirmed its predominant activity in vascular tissues

Constitutive promoters are the most common promoters used to drive the expression of various genes in monocots and dicots. Therefore, it is of intense interest to ascertain their expression patterns in various plant species, organs and during their ontogenic development. In this study, the activity of the CaMV 35S promoter in transgenic tobacco plants was assessed. In contrast to other studies, performed rather on the primary transformants (T₀ generation), here, individuals of T₁ and T₂ generations were used. The expression profiles of the CaMV 35S promoter were tracked within various plant organs and tissues using the GFP marker. Special attention was given to floral tissues for which the original data regarding the CaMV 35S expression were obtained. As expected, distinct developmental and organ/tissue specific expression patterns in a plant body were observed. CaMV 35S activity was detected in most of the plant tissues and during different developmental stages. The GFP signal was not visible in dry seeds only, but it became clearly apparent within 24–48 h after sowing onto the medium, what, among other things, enables the discrimination of transgenic and non-transgenic seeds/seedlings. Afterwards, the most pronounced GFP fluorescence intensity was usually visible in various vascular tissues of both, T₁ and T₂ plants, indicating the high promoter activity. A stable manifestation of the promoter was retained in the next T₂ generation without any evident changes or losses of activity, showing the expression stability of the CaMV 35S.     

Biotechnological approaches for the production of polyhydroxyalkanoates in microorganisms and plants - a review

The increasing effect of non-degradable plastic wastes is a growing concern. Polyhydroxyalkanoates (PHAs), macromolecule-polyesters naturally produced by many species of microorganisms, are being considered as a replacement for conventional plastics. Unlike petroleum-derived plastics that take several decades to degrade, PHAs can be completely bio-degraded within a year by a variety of microorganisms. This biodegradation results in carbon dioxide and water, which return to the environment. Attempts based on various methods have been undertaken for mass production of PHAs. Promising strategies involve genetic engineering of microorganisms and plants to introduce production pathways. This challenge requires the expression of several genes along with optimization of PHA synthesis in the host. Although excellent progress has been made in recombinant hosts, the barriers to obtaining high quantities of PHA at low cost still remain to be solved. The commercially viable production of PHA in crops, however, appears to be a realistic goal for the future.     

The cauliflower mosaic virus (CaMV) 35S promoter sequence alters the level and patterns of activity of adjacent tissue- and organ-specific gene promoters

Here we report the effect of the 35S promoter sequence on activities of the tissue- and organ-specific gene promoters in tobacco plants. In the absence of the 35S promoter sequence the AAP2 promoter is active only in vascular tissues as indicated by expression of the AAP2:GUS gene. With the 35S promoter sequence in the same T-plasmid, transgenic plants exhibit twofold to fivefold increase in AAP2 promoter activity and the promoter becomes active in all tissue types. Transgenic plants hosting the ovary-specific AGL5:iaaM gene (iaaM coding an auxin biosynthetic gene) showed a wild-type phenotype except production of seedless fruits, whereas plants hosting the AGL5:iaaM gene along with the 35S promoter sequence showed drastic morphological alterations. RT-PCR analysis confirms that the phenotype was caused by activation of the AGL5:iaaM gene in non-ovary organs including roots, stems and flowers. When the pollen-, ovule- and early embryo-specific PAB5:barnase gene (barnase coding a RNase gene) was transformed, the presence of 35S promoter sequence drastically reduced transformation efficiencies. However, the transformation efficiencies were restored in the absence of 35S promoter, indicating that the 35S promoter might activate the expression of PAB5:barnase in non-reproductive organs such as calli and shoot primordia. Furthermore, if the 35S promoter sequence was replaced with the NOS promoter sequence, no alteration in AAP2, AGL5 or PAB5 promoter activities was observed. Our results demonstrate that the 35S promoter sequence can convert an adjacent tissue- and organ-specific gene promoter into a globally active promoter. Xuelian Zheng and Wei Deng contributed equally to this work and are considered co-first authors.     

TheCaMV 35S promoter is highly active on floral organs and pollen of transgenic strawberry plants

We have evaluated the expression of the reporter -glucuronidase (GUS) gene driven by the cauliflower mosaic virus 35S (CaMV 35S) promoter in flowers and pollen from 14 independent transgenic strawberry lines. Of the 14 lines evaluated, 13 (92.8%) showed GUS activity—as estimated by the histochemical GUS assay—in some floral organs, with expression being most common in the flower stem, sepals, petals, ovary and stigma. Ten of these thirteen transgenic lines (77%) showed GUS activity in pollen, although the percentages of positive pollen per flower varied greatly among the different lines. A study of the GUS expression during pollen maturation showed that the (CaMV 35S) promoter showed low expression in pollen from flower buds before anthesis but was activated in mature pollen following anther dehiscence. The percentages of pollen grains that showed GUS activity ranged from 2.1% to 46.3%. These percentages were similar or even higher when mature pollen was stored dry at room temperature for 2 weeks. After 5 weeks of storage, the percentages of GUS-positive pollen decreased in two of the six lines analysed but remained at similar values in the other four lines. GUS activity was also measured in protein extracts of mature pollen by means of the fluorometric GUS assay, with the values obtained ranging from 3.8 mol MU mg protein^–1 h^–1 to 0.26 mol MU mg protein^–1 h^–1. Contrary to the generally held view that the CaMV 35S promoter is virtually silent in pollen, we conclude that it is highly expressed in transgenic strawberry pollen.Abbreviations CaMV 35S Cauliflower mosaic virus promoter - GUS -Glucuronidase (EC 3.2.1.31) - MU 4-Methyl umbelliferone - nos Nopaline synthase promoter - nptII Neomycin phosphotransferase - X-Gluc 5-Bromo-4-chloro-3-indolyl--d-glucuronic acid     

拟南芥基因转移新方法一真空渗入法的研究

以拟南芥（Ａｒａｂｉｄｏｐｓｉｓｔｈａｌｉａｎａ）生态型Ｌａｎｄｓｂｅｎｇｅｒｅｃｔａ为试材,在含有所构建的ＣａＭＶＢａｒｉ－１株系基因ＶＩ的质粒（ｐＪＯ５３０Ｂａｒｉ－１ＧＶＩ）的根癌农杆菌（Ａｇｒｏｂａｃｔｅｒｉｕｍｔｕｍｅｆａｃｉｅｎｓ）菌种ＧＶ３１０１的介导下,研究了基因转移的新方法一真空渗入法。这种方法简便、快速、可靠且无需经过组织培养阶段即可获得大量转化植株。适宜的转化条件是将生长健壮,除去主苔后４－８ｄ的成株连同营养钵倒置浸入被渗入培养基稀释的农杆菌孢子悬浮液,其光密度为０．８,在吸力为１．７ｍ２／ｈ的真空泵下断续处理２ｍｉｎ／３０ｓ,置于２４ｈ连续光照下的气候室培养,待种子收获后在含有潮霉素的选择培养基选择转化植株．ＰＣＲ分析及ＥＬＩＳＡ检测,该方法的转化效果高达０．７１％。     

Quantitative analysis of the transgene variability among primary tobacco transformants

The aim of this study was to develop a model for the quantitative estimation of the genetic and environmental variance components in the first generation (T₁) of transgenic plants, in which the transgene effect is considered as a source of genetic variation. The experimental population consisted of T₁ independent transgenic plants (ITPs). Forty-two ITPs of tobacco were generated, containing a chimaeric gene comprising the cauliflower mosaic virus (CaMV) 35S promoter and the reporter gene -glucuronidase (GUS). From each ITP, four cuttings were grown in a randomized block design, and GUS activity in the leaves was determined. The mean GUS activity of the ITPs ranged from 0.55 to 167.9 pmol MU per mg protein per min. Testing of the statistical assumptions of the model revealed a significant scale effect, resulting from correlation between the intra-ITP variance and the average GUS activity of the ITPs. Log GUS activity (LGA) and power of –0.15 of GUS activity (TGA) scale transformations eliminated the scale effect. For GUS activity, the inter-ITP variance was only 28% of the total variance in the experiment, whereas for LGA and TGA it was 72% and 76%, respectively. The opposite was true for the intra-ITP variance, which was reduced from 58% to 18% and 16%, respectively. The experimental design allowed partitioning of the phenotypic variance in T₁ transgenic plants into genetic and environmental components. According to the original scale GUS activity, most of the phenotypic variance was due to environmental variance; the common tendency to interpret this variance as an outcome of position effect and other genetic changes due to transformation leads to incorrect findings. In the present example, after scale transformation the genetic component was 80% of the phenotypic variance.     

Expression of CaMV35S-GUS gene in transgenic rice plants

Summary To understand the properties of the cauliflower mosaic virus (CaMV) 35S promoter in a monocotyledonous plant, rice (Oryza sativa L.), a transgenic plant and its progeny expressing the CaMV35S-GUS gene were examined by histochemical and fluorometric assays. The histochemical study showed that -glucuronidase (GUS) activity was primarily localized at or around the vascular tissue in leaf, root and flower organs. The activity was also detected in the embryo and endosperm of dormant and germinating seeds. The fluorometric assay of various organs showed that GUS activity in transgenic rice plants was comparable to the reported GUS activity in transgenic tobacco plants expressing the CaMV35S-GUS gene. The results indicate that the level of expression of the CaMV 35S promoter in rice is similar to that in tobacco, a dicotyledonous plant, suggesting that it is useful for expression of a variety of foreign genes in rice plants.