Application of ISSR, RAPD, and cytological markers to the certification of Picea mariana, P. glauca, and P. engelmannii trees, and their putative hybrids.

Picea glauca (white spruce) and P. engelmannii (Engelmann spruce) are so similar and integrated that it is impossible to distinguish between them and their hybrids using morphological characteristics. Although natural hybrids between P. glauca and P. mariana (black spruce) do not generally occur, even though the 2 species are sympatric in North America, a first-generation hybrid, called the Rosendahl spruce, has been reported in the literature. In this study, several inter-simple sequence repeat (ISSR) markers were developed, as were randomly amplified polymorphic DNA (RAPD) markers, to certify spruce trees and their hybrids. ISSR fingerprinting was more efficient than RAPD assay; it detected 70% polymorphic DNA markers among the spruce species analyzed, whereas RAPD fingerprinting detected only 53%. Species-diagnostic ISSR and RAPD markers differentiating P. glauca from P. engelmannii and P. mariana were cloned and sequenced. Molecular certification of the spruce samples analyzed confirmed that all the seeds from interior spruce populations were true hybrids of P. glauca and P. engelmannii. But the analysis of seeds derived from the putative Rosendahl spruce indicated that this tree is likely a pure P. glauca genotype, rather than a hybrid of P. glauca and P. mariana. These data were confirmed by cytological analyses. Further analysis, using a more sensitive DNA amplification method with designed primers flanking the species-diagnostic ISSR and RAPD markers, revealed that such sequences are not generally species-specific because they are present in other spruce species.     

Expression of gus in somatic embryo cultures of black spruce after microprojectile bombardment

Immature embryos (stage I) and cotyledonary somatic embryos(stage III) of black spruce [Picea mariana (Mill) B.S.P.] werebombarded with tungsten particles coated with a gene constructcontaining the fusion of gus:: nptll. GUS (ß-glucuronidase)activity was monitored histochemically with X-gluc giving ablue colour where transient gene expression was detected inthe bombarded tissues. A high transient expression of gus wasobserved in stage I embryo cultures 2 d after bombardment (202GUS foci per 300 mg tissue). GUS activity had substantiallydiminished in this material 14 d after bombardment, when grownin liquid LP maintenance medium containing BA (4.4µM),2,4-D (9µM) and 1% sucrose. However, when stage I embryoswere cultured on LP maturation medium containing BA (40 µM),IBA (1 µM), 3.4% sucrose and 0.8% agar, GUS activity after2 d was 335 GUS foci per 300 mg tissue, and the activity wasdetected until 30 d after bombardment. With stage III somaticembryos cultured on LP maintenance medium, 92% showed GUS activity2d after bombardment (16 GUS foci per embryo), and 31 % showedactivity 30 d after bombardment (4 GUS foci per embryo). GUSactivity was still evident in 12% of the embryos (2 GUS fociper embryo) 45 d after bombardment. Key words: Black spruce, gus = E. coli geneuid A encoding ß-glucuronidase, nptll = gene encoding neomycin phos-photransferase, somatic embryos     

Differential gene expression in nematode-induced feeding structures of transgenic plants harbouring promoter—gusA fusion constructs

Sedentary plant-parasitic nematodes are able to induce specialized feeding structures in the root system of their host plants by triggering a series of dramatic cellular responses. These changes presumably are accompanied by a reprogramming of gene expression. To monitor such changes, a variety of promoter— gus A fusion constructs were introduced into Arabidopsis and tobacco. Transgenic plants were analysed histochemically for GUS activity in the nematode feeding structures after infection with either Heterodera schachtii or Meloidogyne incognita . Promoters of the Cauliflower Mosaic Virus 35S gene, the bacterial nopaline synthase, rooting loci ( rol ) and T- cyt genes and the plant-derived phenylalanine ammonia-lyase I gene, which are highly active in non-infected roots, were all downregulated in the feeding structures as indicated by the strong decrease of GUS activity inside these structures. Less stringent down-regulation was observed with chimeric gus A fusion constructs harbouring truncated rol B and rol C promoter sequences. Similar observations were made with transgenic Arabidopsis lines that carried randomly integrated promoterless gus A constructs to identify regulatory sequences in the plant genome. Most of the lines that were selected for expression in the root vascular cylinder demonstrated local down-regulation in feeding structures after infection with H. schachtii . The reverse pattern of GUS activity, a blue feeding structure amidst unstained root cells, was also found in several lines. However, GUS activity that was entirely specific for the feeding structures was not observed. Our data show that the expression of a large number of genes is influenced during the development of the nematode feeding structures.     

Expression of the gus A gene in embryogenic cell lines of Sitka spruce following Agrobacterium-mediated transformation

Transformation of Picea sitchensis (Bong) Carr. was investigatedby incubating embryogenic cell lines, initiated from immatureand mature zygotic embryos, with a supervirulent strain of Agrobacteriumtumefaciens. The latter carried a gus A-intron gene. Transientgene expression was determined histochemically by recordingthe number of distinct areas of ß-glucuronidase (GUS)activity. Maximum expression of the gus gene was achieved witha bacterial suspension with an OD₆₀₀ of 0.8–1.1 dilutedwith an equal volume of MPM medium, Inoculation of cells withbacteria for 30 mm, 72 h co-cultivation period and exposureof Agrobacterium and plant cells to 50 µM acetosyrmngone.These results are discussed in relation to Agrobacterium-mediatedgene delivery for the stable transformation of Sitka spruceand other conifers. Key words: Sitka spruce, Agrobacterium, transformation, embryonal suspensor masses, GUS activity     

The Commelina Yellow Mottle Virus Promoter Is a Strong Promoter in Vascular Tissue of Transgenic Gossypium hirsutum Plants

Explants of cotton (Gossypium hirsutum L. cv. Jingmian 7) were transformed with Agrobacterium tumefaciens (Smith et Townsend ) Conn LBA4404 harboring an expression cassette composed of CoYMV (Commelina Yellow Mottle Virus) promoter-gus-nos terminator on the plant expression vector pBcopd2. Transgenic plants were regenerated and selected on a medium containing kanamycin. GUS (β-glucuronidase) activity assays and Southern blot analysis confirmed that the chimerical gus gene was integrated into and expressed in the regenerated cotton plants. Plant expression vector pBI121 was also transferred into the same cotton variety and the regenerated transgenic plants were used as a positive control in GUS activity analysis. Evidences from histochemical analysis of GUS activity demonstrated that under the control of a 597 bp CoYMV promoter the gus gene was highly expressed in the vascular tissues of leaves, petioles, stems, roots, hypocotyls, bracteal leaves and most of the flower parts while GUS activity could not be detected in stigma, anther sac and developing cotton fibers of the transgenic cotton plants. GUS specific activity in various organs and tissues from transgenic cotton lines was determined and the results indicated that the CoYMV promoter-gus activities were at the same level or higher than that of CaMV 35S promoter-gus in leaf veins and roots where the vascular tissues occupy a relatively larger part of the organs, but in other organs like leaves, cotyledons and hypocotyls where the vascular tissues occupy a smaller part of the organs the CoYMV promoter-gus activity was only 1/3-1/5 of the CaMV 35S promoter-gus activity. The GUS activity ratio between veins and leaves was averaged 0.5 for 35S-GUS plants and about 2.0 for CoYMV promoter-gus transgenic plants. These results further demonstrated the vascular specific property of the promoter in transgenic cotton plants. An increasing trend of GUS activity in leaf vascular tissues of transgenic cotton plants developing from young to older was observed.     

Cloning of the promoter region of plasma membrane aquaporin BnPIP1 from Brassica napus and its functional analysis

Aquaporins make water-selective channels in plants, facilitating the permeation of water through membranes and adjusting water fast transport during seed germination, cell elongation, stoma movement, fertilization and responses to environmental stresses. They belong to the MIP (major intrinsic protein) family with molecular weight of 2629 kD and are characterized by six membrane-spanning a-helixes connected by five loops and short N-terminal and C-terminal domains in the cytoplasm[13]. The p…     

Transformation of white spruce (Picea glauca) somatic embryos by microprojectile bombardment

Cotyledonary somatic embryos of white spruce [Picea glauca (Moench) Voss] were subjected to microprojectile bombardment with a gene construct containing a gus::nptll fusion gene. Somatic embryos were used to re-induce the embryogenic tissue after bombardments. Histochemical assay using X-gluc as a substrate showed that all the embryos (100%) were GUS positive 48 h after bombardment. However, only thirteen out of 605 embryos (2.2%) remained GUS positive after two months in culture. Three of those thirteen (23%) embryo-derived tissues consistently showed GUS activity for eight months in culture. These putatively transfomed embryogenic tissues were subjected to Southern blot analysis and the results suggested integration of the gus::nptll gene expression cassette in the white spruce genome.Abbreviations ABA (±)abscisic acid - BA benzyladenine - bp base pair - 2,4-D 2,4-dichlorophenoxyacetic acid - kb kilobase - gus E. coli gene uid A for -glucuronidase - nptll neomycin phosphotransferase II - X-gluc 5-bromo-4-chloro-3-indolyl--D-glucuronic acid     

New evidence from mitochondrial DNA of a progenitor-derivative species relationship between black spruce and red spruce (Pinaceae)

Mitochondrial DNA (mtDNA) markers were used to assess the genetic diversity in allopatric populations of black spruce (Picea mariana [Mill.] BSP) and red spruce (P. rubens Sarg.). Patterns of mitochondrial haplotypes (mitotypes) were strikingly different between the two species. All mtDNA markers surveyed were polymorphic in black spruce, revealing four different mitotypes and high levels of mtDNA diversity (P(p) = 100%, A = 2.0, H = 0.496). In contrast, populations of red spruce had only two mitotypes and harbored low levels of ggenetic diversity (P(p) = 13.2%, A = 1.1, H = 0.120). When the southernmost allopatric populations of red spruce were considered, only one mitotype was detected. As previously reported for nuclear gene loci, the diversity observed for mtDNA in red spruce was a subset of that found in black spruce. Comparison of present and previously published data supports the hypothesis of a recent progenitor-derivative relationship between these species, red spruce presumably being derived by allopatric speciation of an isolated population of black spruce during the Pleistocene.     

rha1, a gene encoding a small GTP binding protein from Arabidopsis, is expressed primarily in developing guard cells.

The rha1 gene from Arabidopsis encodes a small GTP binding protein belonging to the Ypt/Rab family. Transgenic Arabidopsis plants containing the promoter region of the rha1 gene fused to the beta-glucuronidase (gus) reporter gene revealed gus expression limited mainly to the guard cells of stomata, the stipules, and the root tip of young plants. In flowering plants, expression was found predominantly in the receptacle and in guard cells of the different flower organs. High GUS activity could also be seen in callus tissue and developing seeds. No detectable activity was present in other plant tissues; activity could not be induced by various treatments. GUS activity was visualized histochemically using both 5-bromo-4-chloro-3-indolyl beta-D-glucuronide and a newly developed GUS substrate: Sudan II-beta-glucuronide. The latter precipitates as red crystals at the site of GUS activity. Results obtained by the gus analysis were confirmed by whole-mount mRNA in situ hybridization. A hypothesis for the function of the Rha1 protein is discussed.     

VASA localization requires the SPRY-domain and SOCS-box containing protein,GUSTAVUS

VASA (VAS), a key protein in establishing the specialized translational activity of the Drosophila pole plasm, accumulates at the posterior pole of the developing oocyte. We identified a gene, gustavus (gus), that encodes a protein that interacts with VAS. A gus mutation blocks posterior localization of VAS, as does deletion of a segment of VAS containing the GUS binding site. Like VAS, GUS is present in cytoplasmic ribonucleoprotein particles. Heterozygotes for gus or a deletion including gus produce embryos with fewer pole cells and posterior patterning defects. Therefore, GUS is essential for the posterior localization of VAS. However, gus is not required for the posterior localization of oskar (osk). Apparent gus orthologs are present in mammalian genomes.     

A reliable transformation method and heterologous expression of beta-glucuronidase in Lentinula edodes

A simple and reliable mushroom transformation procedure based on electroporation of basidiospores or mycelial fragments was developed. This method eliminated the problem of protoplast preparation, the transformation efficiency were 30-150 transformants per mug DNA and the hygromycin resistant marker gene and gus were expressed in Lentinula edodes successfully. No false positive antibiotic-resistant cultures were detected by PCR amplification and the beta-glucuronidase (GUS) expression was maintained stable during mitotic cell division without selection pressure for more than 6 months. Southern analysis of transformants indicated the integration of gene might occur by non-homologous recombination. Using the glyceraldehyde-3-phosphate dehydrogenase (gpd) promoter with the first intron of gpd gene, the average GUS activity in L. edodes reached 144.6+/-3.9 U mg(-1) soluble protein, while only 30.1+/-0.7 U mg(-1) soluble protein was detected for those without the intron. The percentage of GUS in total soluble protein was 5.67 x 10(-4) (0.06%) for the transformant with the highest GUS activity. This rapid and convenient electroporation procedure offers a new approach for the genetic manipulation and tool to tag genes of important edible mushroom species.     

A promoter from the loblolly pine PtNIP1;1 gene directs expression in an early-embryogenesis and suspensor-specific fashion

The PtNIP1;1 gene encodes an aquaglyceroporin that is expressed early in embryogenesis and appears to be expressed preferentially in the suspensor [V.T. Ciavatta et al. (2001) Plant Physiol 127:211-224]. An 899-bp fragment 5' to the PtNIP1;1 open reading frame (NIP(-899)) was cloned from loblolly pine (Pinus taeda L.) genomic DNA and fused to the beta-glucuronidase (GUS) reporter gene. The resulting plasmid, pNIP-GUS, was transformed into Norway spruce (Picea abies L.) embryogenic cultures by co-bombarding with a plasmid containing a bar gene construct as a selectable marker. The identity of lines selected on medium containing the herbicide Basta and showing beta-glucuronidase activity was confirmed by polymerase chain reaction as harboring GUS. Histochemical GUS assays of these lines revealed GUS activity in all cells of proembryogenic masses. During early embryogeny, GUS staining was intense in the suspensor region but not detectable in embryonal masses. GUS staining was absent by mid-embryogeny. By contrast, a control transgenic line, transformed with EuCAD-GUS, expressed GUS throughout embryo development. These results suggest that NIP(-899) contains elements that drive early embryogenesis-specific expression and suspensor-specific expression. This is the first example of a suspensor-specific promoter in conifers.     

抗除草剂转基因大豆后代遗传分析

分析了来源于农杆菌介导的4个独立的大豆转化系的后代遗传特性。分别采用种子切片GUS染色方法和除草剂涂抹以及喷洒方法检测gus报告基因和抗除草剂bar基因在后代的表达。其中3个转化系T1代gus基因和bar基因能够以孟德尔方式3：1连锁遗传,说明这2个基因整合在大豆基因组的同一位点。这3个转化系在T2代获得了纯合的转化系,并能够稳定遗传至T5代。有一个转化系在T1代GUS和抗除草剂检测都为阴性,但通过Southern杂交证明转基因存在于后代基因组,显示发生了转基因沉默。为了证明转基因沉默是转录水平还是转录后水平,T1代植物叶片接种大豆花叶病毒（SMV）并不能抑制转基因沉默,说明该转化系基因沉默可能不是发生在转录后水平。     

Genetic transformation of Ginkgo biloba by Agrobacterium tumefaciens

A reproducible protocol has been established for the transformation of Ginkgo biloba by Agrobacterium tumefaciens . Embryos were co-cultivated with Agrobacterium tumefaciens GV3101 (pGV2260) carrying the binary vector pTHW136, which contained the gus reporter gene and the nptII selectable gene, encoding the enzymes β -glucuronidase (GUS) and neomycin phophotransferase II, respectively. Transient GUS activity has been used to screen the effects of different factors on the transfer of DNA into embryos (age of embryos, infection method, composition of co-cultivation medium). Then, experimental conditions have been defined to obtain transgenic kanamycin-resistant G. biloba calluses expressing GUS activity. The highest rate of transformation (45%) was reached using 1.5-month-old embryos co-cultivated on a medium lacking mineral elements. The integration of gus and nptII genes in calluses was confirmed by polymerase chain reaction analysis and Southern blot analysis.     

Use of the signal peptide of Pisum vicilin to translocate beta-glucuronidase in Nicotiana tabacum.

A hybrid protein system was used for the study of protein transport in plant cells. A nucleotide sequence (vic) encoding a putative signal peptide of 15 amino acid residues, derived from the published aa sequence of one Pisum vicilin, was synthesized and fused in frame to the gus gene encoding a bacterial cytosolic beta-glucuronidase (GUS). When the hybrid vic::gus gene was expressed in tobacco cells using the cauliflower mosaic virus 35S promoter, the hybrid GUS protein was targeted to, and glycosylated inside the rough endoplasmic reticulum. Glycosylation could be blocked with the antibiotic tunicamycin. The study of transient expression in protoplasts showed that extracellular secretion efficiency was low, which may be due to the nature of the GUS protein.