Granule-bound starch synthase I is responsible for biosynthesis of extra-long unit chains of amylopectin in rice

A rice Wx gene encoding a granule-bound starch synthase I (GBSSI) was introduced into the null-mutant waxy (wx) rice, and its effect on endosperm starches was examined. The apparent amylose content was increased from undetectable amounts for the non-transgenic wx cultivars to 21.6-22.2% of starch weight for the transgenic lines. The increase was in part due to a significant amount of extra-long unit chains (ELCs) of amylopectin (7.5-8.4% of amylopectin weight), that were absent in the non-transgenic wx cultivars. Thus, actual amylose content was calculated to be 14.9-16.0% for the transgenic lines. Only slight differences were found in chain-length distribution for the chains other than ELCs, indicating that the major effect of the Wx transgene on amylopectin structure was ELC formation. ELCs isolated from debranched amylopectin exhibited structures distinct from amylose. Structures of amylose from the transgenic lines were slightly different from those of cv. Labelle (Wx(a)) in terms of a higher degree of branching and size distribution. The amylose and ELC content of starches of the transgenic lines resulted in the elevation of pasting temperature, a 50% decrease in peak viscosity, a large decrease in breakdown and an increase in setback. As yet undetermined factors other than the GBSSI activity are thought to be involved in the control of formation and/or the amount of ELCs. Structural analysis of the Wx gene suggested that the presence of a tyrosine residue at position 224 of GBSSI correlates with the formation of large amounts of ELCs in cultivars carrying Wx(a).     

转反义Wx基因水稻颖果中与淀粉合成和积累相关酶活性的变化

将反义Wx基因转入水稻,导致Wx蛋白不同程度减少,颖果中的直链淀粉含量不同程度下降,总淀粉含量显著降低,直链淀粉与总淀粉的比值极显著降低。在水稻颖果发育过程中,ADPG-PPase、GBSS、SSS和SBE的活性在灌浆前期迅速升高,达最大值后很快下降,在灌浆中后期下降趋缓。Wx蛋白减少后的转基因水稻颖果中的GBSS活性明显下降,下降幅度与直链淀粉含量相一致,而且活性高峰期比其亲本有所提前。转基因水稻颖果中ADPG-PPase和SSS的活性在颖果发育的前中期,SBE则在中后期高于相应的亲本。     

水稻Wx基因表达调控的研究进展

水稻Wx基因编码颗粒结合淀粉合成酶(GBSS),是控制直链淀粉合成的主效基因。文中主要从转录水平和转录后水平介绍水稻Wx基因表达调控的研究进展,同时介绍转基因、遗传背景以及环境温度对Wx基因表达的影响,并提出Wx基因表达调控研究中一些期待解决的问题。     

复合调控Wx与SBE3基因对水稻籽粒直链淀粉含量的影响

颗粒淀粉合成酶（GBSS）和淀粉分支酶3（SBE3）是淀粉合成过程中的两个关键酶,这两个酶主要由耽和SBE3两个基因分别控制,它们的表达量直接影响直链淀粉和支链淀粉的含量比例。为了探讨水稻淀粉关键酶基因耽过量与SBE3干涉复合表达对直链淀粉含量的影响,构建了Wx过量表达与SBE3干涉结合的多基因表达载体,并通过农杆菌介导的方法将其导入日本晴水稻中。经过PCR检测分析获得了65株转基因阳性植株,半定量RT—PCR检测表明转基因株系中Wx基因表达量明显增加,而SBE3基因表达量显著减少。转基因株系籽粒透明度明显降低,直链淀粉含量比野生型的平均高45％,但是千粒重变化不大,与野生型相当。遗传分析表明这些转基因株系多数可稳定遗传。     

Estimating the copy number of transgenes in transformed rice by real-time quantitative PCR

In transgenic plants, transgene copy number can greatly influence the expression level and genetic stability of the target gene, making estimation of transgene copy number an important area of genetically modified (GM) crop research. Transgene copy numbers are currently estimated by Southern analysis, which is laborious and time-consuming, requires relatively large amounts of plant materials and may involve hazardous radioisotopes. We report here the development of a sensitive, high-throughput real-time (RT)-PCR technique for estimating transgene copy number in GM rice. This system uses TaqMan quantitative RT-PCR and comparison to a novel rice endogenous reference gene coding for sucrose phosphate synthase (SPS) to determine the copy numbers of the exogenous beta-glucuronidase (GUS) and hygromycin phosphotransferase (HPT) genes in transgenic rice. The copy numbers of the GUS and HPT in primary rice transformants (T0) were calculated by comparing quantitative PCR results of the GUS and HPT genes with those of the internal standard, SPS. With optimized PCR conditions, we achieved significantly accurate estimates of one, two, three and four transgene copies in the T0 transformants. Furthermore, our copy number estimations of both the GUS reporter gene and the HPT selective marker gene showed that rearrangements of the T-DNA occurred more frequently than is generally believed in transgenic rice.     

Development of transgenic rice plants overexpressing the Arabidopsis H+/Ca2+ antiporter CAX1 gene

The gene of the Arabidopsis thaliana H+/Ca2+ transporter, CAX1 (cation exchanger 1) was introduced into Japonica cultivars of rice (Ilpumbyeo) by Agrobacterium-mediated transformation, and a large number of transgenic plants were produced. The neomycin phosphotransferase II (NPTII) gene was used as a selectable marker. The activity of neomycin phosphotransferase could be successfully detected in transgenic rice callus. The introduction of the CAX1 gene was also proven by PCR using CAX1-specific oligonucleotide primers in regenerated plants. Stable integration and expression of the CAX1 gene in T0 plants and T1 progeny were confirmed by DNA hybridization, Northern blot analysis, and luminescent analysis.     

Agrobacterium-mediated transformation of Javanica rice cv. Rojolele

The Agrobacterium-mediated transformation system was extended to a famous Javanica rice variety, Rojolele, that is cultivated in Indonesia now. Efficient callus induction from immature and mature seeds of Rojolele did not succeed by any previous method for any rice cultivar. In this study, the callus from mature seeds of Rojolele exhibited a compact and nodular appearance on C medium after the carbon source and medium pH was modified. Scutellum-derived calli from mature seeds were co-cultivated with Agrobacterium tumefaciens strains EHA101 or LBA4404 that carried plasmid pAFT14, which contained the genes for beta-glucuronidase (gus) and hygromycin resistance (hpt). Finally, the transformation efficiency of Rojolele variety using A. tumefaciens strain EHA101 (pAFT14) was improved to about 23%, similar to that of the Japonica rice variety Nipponbare. The seed fertility of transgenic Rojolele was more than 90%. The copy number of the transgene varied from one to three copies in the T(0) transgenic lines. Both the gus and the hpt genes were inherited and expressed in the progeny.     

Transcriptional silencing and developmental reactivation of cry1Ab gene in transgenic rice

One transgenic rice line lacking CrylAb expression product was screened in the progenies of Agrobacterium-transformed transgenic rice variety Zhong 8215 with a cry1Ab gene under field releasing conditions by using GUS histochemical assay and Western blot. Molecular hybridization results revealed that the crylAb gene was silenced in the transgenic rice variety Zhong 8215 and two copies of ubiquitin promoter were integrated into the rice genome. The silencing of crylAb gene in transgenic rice was found to be due to the methylation of the ubiquitin promoter as revealed by methylation analysis. Meanwhile, different concentrations of demethylation reagent 5-azacytidine combining with different treatment time were employed to treat the silenced transgenic rice seeds. The results indicated that 5-azacytidine could reactivate 8%-30% of the silenced transgenic rice plants and the expression level of the reactivated cry1Ab transgene could reach as high as 0.147% of the total soluble protein. Treatment with low con     

作物淀粉生物合成与转基因修饰研究进展

淀粉是高等植物中碳水化合物的主要贮藏形式 ,也是粮食作物产品的最主要成分。淀粉虽然都由直链淀粉和枝链淀粉组成 ,但在不同作物中两者的比例和枝链淀粉结构的存在很大差异。现已明确 ,直链淀粉是在颗粒结合淀粉合成酶 (granule boundstarchsynthase,GBSS)催化下合成的 ,而枝链淀粉是四种酶共同作用的结果 ,它们分别是腺嘌呤 -葡萄糖焦磷酸化酶 (ADP glucosepyrophosphorylase ,AGP) ,可溶性淀粉合成酶 (solublestarchsynthase ,SSS) ,淀粉分枝酶 (starchbranchingenzyme ,SBE)和脱分枝酶 (starchdebranchingenzyme ,DBE)。一方面 ,在不同作物中 ,这些酶本身存在多种形式 ,如在玉米胚乳中 ,AGP有大亚基和小亚基之分 ,SBE又可分BE1,BEIIa ,BEIIb 3种 ,SSS也可分为SSI和SSIII(或SSIIa)两种 ,而DBE也有异淀粉酶 (isoamylase)和限制性糊精酶 (pullu lanase)两种。另一方面 ,控制特定酶的基因 ,在不同作物甚至在同一种作物的不同品种中也可能存在不同的复等位基因 ,如籼稻和粳稻的GBSS分别由蜡质基因Wxa 和Wxb 控制 ,两者编码的GBSS活性差异显著。此外 ,环境条件也可通过影响基因的转录使酶的含量或催化性能发生变化。迄今 ,国内外已获得多种马铃薯和水稻的转基因材料 ,对淀粉合成进行修饰 ,试图培育优质品     

Improved frequency of transformation in rice and maize by treatment of immature embryos with centrifugation and heat prior to infection with Agrobacterium tumefaciens

The efficiency of transformation was improved by treating immature embryos with heat and centrifugation before infection with Agrobacterium tumefaciens in rice and maize. Because the effects were detected both in the levels of transgene expression after co-cultivation and in the number of independent transgenic plants obtained per embryo, conditions were first optimized based on the transgene expression, and then transformants were produced. The optimal conditions varied considerably depending on species and genotypes, but reasonably good parameters were identified for Japonica rice, Indica rice or maize. As a general tendency, the effect of centrifugation was greater than that of heat in Japonica rice, whereas that of heat was greater than that of centrifugation in Indica rice and maize A188, and the combination of the treatments was the most effective in all of the genotypes tested. The frequency of transformation was improved several fold in rice and maize. In addition, transformation of certain genotypes of maize, which were not transformable before, and transformation of maize with a less efficient vector, which could not transform maize before, became possible by these pre-treatments. In the highest case, 18 independent transgenic plants were obtained from a single immature embryo of Japonica rice. Although nothing is known about the mechanism, these pre-treatments seemed to render cells of rice and maize more competent for transformation mediated by A. tumefaciens.     

水稻基因组加倍对籽粒大小调控基因表达的影响

水稻是最重要的粮食作物之一,提高水稻产量一直是育种的主要目标。水稻四倍体相对于二倍体具有籽粒变大、粒重增加的特点,研究基因组加倍后籽粒大小基因的调控模式,在育种应用方面具有十分重要的意义。本文以二倍体 -四倍体水稻为材料,分析6个控制籽粒大小基因在幼穗发育中的表达差异,同时结合转基因实验,探讨基因剂量增加对基因表达水平和籽粒大小的影响。结果发现：基因组加倍后,水稻的发育进程不变,但株高增加,叶片变宽,籽粒变大,增大后的籽粒在籼稻表现为长、宽均增加显著,而在粳稻中长度比宽度增加更为明显。进一步分析控制籽粒大小基因的表达差异情况,发现这些基因的表达不仅受发育时期的影响,在籼粳亚种间也明显不同,即受遗传背景的影响。在基因组加倍的情况下,正调控基因GS5、HGW的表达普遍高于对应的二倍体;负调控基因GS3在籼稻D9311中趋于下调或沉默,而在粳稻DBl中趋于上调,GW2在D9311中上调,而在DBl中趋于沉默。通过转基因实验分析负调控基因GW2在二倍体Bl中的表达趋势,发现其在基因剂量线性增加的情况下,表达水平高于二倍体和四倍体,导致其籽粒变小。本研究结果有助于了解水稻中控制籽粒大小的基因在二倍体和四倍体中的表达模式,为高产育种提供理论依据。     

Transgenic rice plants expressing a Bacillus subtilis protoporphyrinogen oxidase gene are resistant to diphenyl ether herbicide oxyfluorfen

Protoporphyrinogen oxidase (Protox), the penultimate step enzyme of the branch point for the biosynthetic pathway of Chl and hemes, is the target site of action of diphenyl ether (DPE) herbicides. However, Bacillus subtilis Protox is known to be resistant to the herbicides. In order to develop the herbicide-resistant plants, the transgenic rice plants were generated via expression of B. subtilis Protox gene under ubiquitin promoter targeted to the cytoplasm or to the plastid using Agrobacterium-mediated gene transformation. The integration and expression of the transgene were investigated at T0 generation by DNA and RNA blots. Most transgenic rice plants revealed one copy transgene insertion into the rice genome, but some with 3 copies. The expression levels of B. subtilis Protox mRNA appeared to correlate with the copy number. Furthermore, the plastidal transgenic lines exhibited much higher expression of the Protox mRNA than the cytoplasmic transgenic lines. The transgenic plants expressing the B. subtilis Protox gene at T0 generation were found to be resistant to oxyfluorfen when judged by cellular damage with respect to cellular leakage, Chl loss, and lipid peroxidation. The transgenic rice plants targeted to the plastid exhibited higher resistance to the herbicide than the transgenic plants targeted to the cytoplasm. In addition, possible resistance mechanisms in the transgenic plants to DPE herbicides are discussed.     

Rapid PCR-based determination of transgene copy number in rice

We present a simple, rapid, and low-cost method to determine transgene copy number in rice. More than 100 first- and second-generation transgenic rice plants were tested. The plasmid (pRCopy) used for rice transformation contains the specific gene of interest and a partially deleted cytochrome c gene (cyc), a single-copy gene in rice. A 132-bp segment of the cloned ricecyc was shortened to 108 bp by deleting a 24-bp internal fragment. After PCR amplification of the genomic DNA from transgenic rice harboring pRCopy, the 2 expected bands were found. The 121-bp band corresponds to the endogenouscyc; the 97-bp band comes from the integrated pRCopy. Clear distinctions can be made between single and multiple copies of the transgene by comparing band densities.