Upstream regulatory regions from the maize Sh1 promoter confer tissue-specific expression of the ,-glucuronidase gene in tomato

A promoter fusion (Sh35) combining upstream regulatory regions from the maize Sh1 promoter with a truncated 35S promoter, Δ9035 (–90 to +8) has been compared with the original Sh1 promoter for its capacity to promote expression of the β-glucuronidase (GUS) gene in stably transformed tomato plants. For both promoters, very faint GUS expression was detected in the vegetative tissues, and no expression was detected in the fruit pericarp tissues. However, in the seed, Sh1 promoted low GUS expression but Sh35 directed 25-fold higher GUS expression. For both constructs, the profile of GUS expression was similar to that of endogenous sucrose synthase activity, but maximal GUS activity was reached 15 days after the peak of sucrose synthase activity. Received: 20 October 1998 / Revision received: 1 December 1998 / Accepted: 14 December 1998     

选择标记可去除的植物高效表达载体的构建

在常用的植物组成型表达载体pBI121的选择标记基因NPTII两侧插入同向的lox位点并用多克隆位点(MCS)取代了GUS基因序列,构建了NPTII基因可被去除的和可插入目的基因的通用植物表达载体pBI121-lox-MCS。替换pBI121-lox-MCS中驱动目的基因表达的35S启动子,可构建成一系列具有其他表达特性的植物表达载体,如本文描述的韧皮部特异表达载体pBdENP-lox-MCS。为方便地筛选去除选择标记基因的转基因植物,还构建了绿色荧光蛋白(GFP)表达框与NPTII表达框连锁的pBI121-gfp-lox-MCS载体。上述植物表达载体可广泛应用于培育选择标记可去除的转基因植物。     

Variability of organ-specific gene expression in transgenic tobacco plants

Variability of expression of introduced marker genes was analysed in a large number of tobacco regenerants from anAgrobacterium-mediated transformation. In spite of standardization of sampling, considerable variation of GUS and NPTII expression was observed between individual transformants at different times of analysis and in different parts of the same plant. Organ-specificity of root versus leaf expression conferred by the par promoter from the haemoglobin gene ofParasponia andersonii in front of thegus gene showed a continuous spectrum. GUS expression in roots was found in 128 out of 140 plants; expression in leaves was found in 46 plants, and was always lower than in the corresponding roots. NPTII expression regulated by the nos promoter also showed a continuous spectrum. Expression levels were generally higher in roots than in leaves. Plants with high GUS expression in leaves showed high NPTII activity as well. A positive correlation between the level of NPTII expression and the numbers of integrated gene copies was noted. Chromosomal position effects and physiological determination are suggested as triggers for the variations. The transformed regenerated tobacco plants were largely comparable to clonal variants.     

Tobacco (Nicotiana tobaccum) nuclear transgenics with high copy number can express NPTII driven by the chloroplast psbA promoter

A chloroplast expression vector containing the NPTII gene under the control of apsbA promoter (psbA-NPTII) was constructed, and was biolistically delivered into both suspension cells and leaf strips of tobacco (Nicotiana tabaccum). Analyses of subsequently recovered kanamycin-resistant transgenic plants indicate that the psbA-NPTII gene was not located in the chloroplast, but was in the nucleus in very high copy number. This conclusion was based upon results from: (1) Southern hybridization analyses of chloroplast and nuclear DNAs using NPTII, chloroplast-marker, and nuclear-marker probes; (2) pulse-field gel electrophoresis; and (3) kanamycin screening of sexual progenies. This study suggests that the nuclear expression of the NPTII gene may have been associated with many copies of the psbA-NPTII construction. Very high copy number in the nucleus might either allow NPTII expression from the otherwise inadequate psbA promoter, or might increase the chance of recombining with upstream tobacco regulatory sequences.