Metabolic state and cell cycle as determinants of facilitated uptake of genetic information by yeast <Emphasis Type="Italic">Saccharomyces cerevisiae</Emphasis>

The transformation efficiency of yeast cells during exponential growth might be characterised as undulatory. The aim of the study was to investigate the reason for the fluctuation in transformation efficiency of yeast Saccharomyces cerevisiae p63-DC5 cells during exponential growth. The heightened response to exogenous DNA was observed with the growing yeast culture when budded cells were predominant. To confirm this phenomenon we carried out synchronization of yeast cells with 10 mM hydroxyurea. Results showed that synchronous yeast cells in the S-phase of cell cycle have enhanced transformation efficiency. Furthermore, S. cerevisiae p63-DC5 cells in the S-phase were successfully transformed with plasmid pl13 in the absence of lithium acetate. We indicated that the permeability of yeast cells in the S-phase to tetraphenylphosphonium (TPP) cations was significantly higher than in asynchronous culture. The results of our study showed that the fluctuation in transformation efficiency was strictly dependent on the metabolic state of yeast cells and the capacity of the yeast cells to become competent was related to the S-phase of cell cycle.     

Genetic Integration in the Heterospecific Transformation of Haemophilus influenzae Cells by Haemophilus parainfluenzae Deoxyribonucleic Acid

The in vivo chemical linkage of Haemophilus parainfluenzae deoxyribonucleic acid (DNA) with the H. influenzae genome has been found to occur at a much higher level than is suggested by the low efficiency of the heterospecific transformation of an antibiotic resistance marker. This linkage, about 60% of the level with homospecific DNA, was found to involve alkali-stable bonding. The amount of host DNA label released (about 60%) was about the same as that released during homospecific transformation. Also, over 60% of the H. influenzae cells adsorbing H. parainfluenzae DNA could not form colonies upon plating. This lethality of the heterospecific transformation was not immediate but followed considerable metabolic activity of the host cells. These data are presented to show that the "limited-pairing" hypothesis may be only a partial explanation for the low efficiency of heterospecific transformation. Another hypothesis is presented which takes into account the lethal effect of this kind of transformation.     

Reasons for lower transformation efficiency in indica rice using Agrobacterium tumefaciens-mediated transformation: lessons from transformation assays and genome-wide expression profiling

Agrobacterium tumefaciens-mediated genetic transformation has been routinely used in rice for more than a decade. However, the transformation efficiency of the indica rice variety is still unsatisfactory and much lower than that of japonica cultivars. Further improvement on the transformation efficiency lies in the genetic manipulation of the plant itself, which requires a better understanding of the underlying process accounting for the susceptibility of plant cells to Agrobacterium infection as well as the identification of plant genes involved in the transformation process. In this study, transient and stable transformation assays using different japonica and indica cultivars showed that the lower transformation efficiency in indica rice was mainly due to the low efficiency in T-DNA integration into the plant genome. Analyses of the global gene expression patterns across the transformation process in different varieties revealed major differences in the expression of genes responding to Agrobacterium within the first 6 h after infection and more differentially expressed genes were observed in the indica cultivar Zhenshan 97 (ZS), with a number of genes repressed early during infection. Microarray analysis revealed an important effect of plant defense response on Agrobacterium-mediated transformation. It has been shown that some genes which may be necessary for the transformation process were down-regulated in the indica cultivar ZS. This dataset provided a versatile resource for plant genomic research to understand the regulatory network of transformation process, and showed great promise for improving indica rice transformation using genetic manipulation of the rice genome.     

Inhibition of protein synthesis enhances transformation of primary cells by viral DNA

Inhibition of protein synthesis by cycloheximide after transfection and subsequent removal of the drug increased the transformation efficiency of primary cells by plasmids containing the left 4.5, 6.7, or 16% of the adenovirus (Ad) genome. The enhancement factor ranged from 2 to as much as 70 depending on the size of the viral DNA fragments used. Addition of cycloheximide before or at the time of transfection inhibited transformation, suggesting that viral protein synthesis is important during the early phase of transformation. Transient expression assays showed that cells treated with cycloheximide post-transfection contained as much as three times the amount of viral RNA transcribed from regions E1A and E1B. Conversion of a rat cell line lacking thymidine kinase activity (TK-) to the TK+ phenotype by a plasmid containing the herpes TK gene was severely inhibited by the drug treatment, suggesting that the enhancement effects of cycloheximide on transformation may be specific for Ad DNA. Cycloheximide treatment also increased the number of transformants induced by a transformation defective E1B mutant of Ad12 (cyt mutant). Plasmid containing only the E1A region of Ad12 transformed primary rat kidney cells with very low efficiency. The inclusion of E1B in the transfecting DNA fragments increased the transformation frequency by more than 400-fold, much higher than that achieved by cycloheximide. Thus, cycloheximide cannot replace E1B functions in transformation efficiency.     

DNA-mediated gene transfer as an indicator of DNA damage and its repair by recipient cells

Preparations of plasmid containing the thymidine kinase gene (pHSV106) were treated with the alkylating agents methyl methanesulphonate or N-methyl-N-nitrosourea prior to transfection into thymidine kinase-deficient mouse L-cells using the DNA-calcium phosphate co-precipitation technique. Relative to transfection with unmodified plasmid, a reduced transformation efficiency was observed using alkylation-damaged plasmid, N-methyl-N-nitrosourea causing the greatest inhibition. Treatment of recipient cells with arabinosyl cytosine or dideoxythymidine during the expression period following transfection by the 'damaged' plasmid reduced transformation efficiency, suggesting that DNA repair 4-6 h post-transfection was required for gene expression.     

Lipoic acid—an unique plant transformation enhancer

Including lipoic acid (LA) in culture media during Agrobacterium transformation processes of four crop species has significantly improved the transformation methods of the crops, even for previously recalcitrant genotypes. Plant transformation efficiency of soybean was significantly increased from 0.6% to 3.7% and tomato from 29.8% to 87.0%. Transformation efficiency was doubled from 2.8% to 5.7% in wheat. The frequency of glyphosate-resistant embryos had a significant increase from 41.4% to 61.2% in cotton. Regeneration of non-transgenic shoots under selection (“shoot escapes”) was significantly reduced in tomato from 91.5% to 46.2% while in soybean from 92.0% to 72.0% under optimal conditions. This study also demonstrated that the increase of transformation efficiency in tomato was accompanied by as much as a significant 2-fold reduction in severity of browning of Agrobacterium-infected plant tissues and up to a significant 3-fold increase in the percentage of explants with a high level of transient gene expression. LA application in plant transformation has enabled the resolution of three common problems in plant transformation: browning or necrosis of the transformed cells or tissues, difficulty in regenerating transformed cells or tissues, and shoot escapes, which severely limit the number of transgenic plants that can be regenerated.     

Optimum conditions for transformation of Synechocystis sp. PCC 6803

This study was conducted to determine the optimal conditions for introduction of exogenous DNA into Synechocystis sp. PCC 6803. Of the three transformation techniques studied, electroporation, ultrasonic transformation and natural transformation, natural transformation showed the highest efficiency. Additionally, this study demonstrated that the higher plasmid concentration and longer homologous recombining fragments resulted in a greater number of transformants. For successful transformation, the lowest concentration of plasmid was 0.02 microg/ml, and the shortest homologous recombining fragment was 0.2 kb. Use of Synechocystis sp. PCC 6803 in the logarithmic growth phase resulted in two-fold higher transformation rate than that of the same organism when cells in the latent phase or the plateau phase were used for transformation. Pretreatment of the host strain, Synechocystis sp. PCC 6803, with EDTA (2 mM) for two days prior to transformation increased the transformation efficiency by 23%. Additionally, incubation of the cells and DNA for 5 h under light conditions increased the transformation efficiency by two orders of magnitude. Moreover, recovery treatment of the cells before they were plated onto antibiotic medium also increased the transformation efficiency.     

Effect of starvation and chloramphenicol on acceleration of bacterial dihexyl sulfosuccinate biotransformation

Starvation for carbon and energy sources accelerated the biotransformation of the anion-active surfactant dihexyl sulfosuccinate (DHS) byComamonas terrigena cells. Cloramphenicol (Cm) added at different time intervals to non-starved cells inhibited the DHS transformation. The largest difference between cells treated and non-treated by Cm was observed for a 16-h-starvation period. Protein synthesisde novo during starvation enhanced the DHS biotransformation efficiency. A partial transformation of DHS in the presence of Cm indicated the constitutive character of enzymes involved in primary DHS biodegradation.     

Studies on transformation in Shigella

Transformation of pBR322 DNA into Shigella occurred at a low frequency. The efficiency of transformation was highest in S. dysenteriae 1 and lowest in S. flexneri. Treatment of cells with CaCl2 for a prolonged period (24h) increased the efficiency of transformation in all strains, except in S. flexneri, where transformation efficiency could not be improved by a variety of manipulations. Transformation efficiency did not increase in any of the strains when transformation was carried out with plasmid DNA obtained from a transformant (homologous transformation), suggesting the absence of a strong restriction-modification system. Extracellular deoxyribonuclease (DNase) levels were low in all the strains tested, but the levels of endogenous DNAse, released after CaCl2 treatment or sonication of the cells, were high. Washing the cells with a solution of CaCl2 did not enhance transformation, suggesting that endogenous DNase could be a significant factor affecting transformation efficiency in species of Shigella.     

Three phases in transformation of human lymphocytes by Epstein-Barr virus, as revealed by colony formation in soft agar

Human cord lymphocytes were examined for colony formation in soft agar medium at various times after infection with Epstein-Barr virus (EBV). The transformation process could be divided into the following three sequential phases: (1) A pre-early phase, lasting about 10 hr post infection (pi), during which the number of transformed colonies was virus dose dependent. (2) An early phase, between about 10 and 60 hr pi, during which cloning efficiency was markedly lower than that of the pre-early phase. (3) A later phase, starting at about 60 hr pi, during which cloning efficiency was restored and the number of colony formers increased in an exponential fashion. EBV-associated nuclear antigen-positive cells first appeared at the beginning (12 hr pi) of the early phase and increased continuously thereafter. Increased DNA synthesis began at about 48 hr pi. These results suggest that the cloning efficiency of the infected cells changes during the transformation process, possibly reflecting altered cell sensitivity to agar.     

Optimal conditions for genetic transformation of the cyanobacterium Anacystis nidulans R2

Under optimal conditions, the cyanobacterium Anacystis nidulans R2 was transformed to ampicillin resistance at frequencies of greater than 10(7) transformants per microgram of plasmid (pCH1) donor DNA. No stringent period of competency was detected, and high frequencies of transformation were achieved with cultures at various growth stages. Transformation increased with time after addition of donor DNA up to 15 to 18 h. The peak of transformation efficiency (transformants/donor molecule) occurred at plasmid concentrations of 125 to 325 ng/ml with an ampicillin resistance donor plasmid (pCH1) and 300 to 625 ng/ml for chloramphenicol resistance conferred by plasmid pSG111. The efficiency of transformation was enhanced by excluding light during the incubation or by blocking photosynthesis with the electron transport inhibitor 3-(3, 4-dichlorophenyl)-1, 1-dimethylurea (DCMU) or the uncoupler carbonyl cyanide-m-chlorophenyl hydrazone. Preincubation of cells in darkness for 15 to 18 h before addition of donor DNA significantly decreased transformation efficiency. Growth of cells in iron-deficient medium before transformation enhanced efficiency fourfold. These results were obtained with selection for ampicillin (pCH1 donor plasmid)- or chloramphenicol (pSG111 donor plasmid)-resistant transformants. Approximately 1,000 transformants per microgram were obtained when chromosomal DNA from an herbicide (DCMU)-resistant mutant was used as donor DNA. DCMU resistance was also transferred to recipient cells by using restriction fragments of chromosomal DNA from DCMU-resistant mutants. This procedure allowed size classes of fragments to be assayed for the presence of the DCMU resistance gene.     

Transient transformation and RNA silencing in Zinnia tracheary element differentiating cell cultures

The Zinnia elegans cell culture system is a robust and physiologically relevant in vitro system for the study of xylem formation. Freshly isolated mesophyll cells of Zinnia can be hormonally induced to semisynchronously transdifferentiate into tracheary elements (TEs). Although the system has proven to be valuable, its utility is diminished by the lack of an efficient transformation protocol. We herein present a novel method to introduce DNA/RNA efficiently into Zinnia cells by electroporation-based transient transformation. Using reporter gene plasmids, we optimized the system for efficiency of transformation and ability for the transformed cells to transdifferentiate into TEs. Optimal conditions included a partial digestion of the cell walls by pectolyase, a low voltage and high capacitance electrical pulse and an optimal medium to maintain cell viability during transformation. Beyond the simple expression of a reporter protein in Zinnia cells, we extended our protocol to subcellular protein targeting, simultaneous co-expression of several reporter proteins and promoter-activity monitoring during TE differentiation. Most importantly, we tested the system for double-stranded RNA (dsRNA)-induced RNA silencing. By introducing in vitro -synthesized dsRNAs, we were able to phenocopy the Arabidopsis cellulose synthase (CesA) mutants that had defects in secondary cell-wall synthesis. Suppressing the expression of Zinnia CesA homologues resulted in an increase of abnormal TEs with aberrant secondary walls. Our electroporation-based transient transformation protocol provides the suite of tools long required for functional analysis and developmental studies at single cell levels.     

Development of an airgun device for particle bombardment

Construction and operation of an airgun device for transient gene-expression studies in monocots is described. Compressed air in a cylinder of an airgun was used as the source of propulsion for DNA-coated gold or tungsten particles. Under a partial vacuum of 700 mm Hg, velocity of the macrocarrier was measured at 520 m sec^?1 and 432 m sec^?1 at atmospheric pressure. Optimum distance from the stopping plate to different target cells during bombardment ranged from 4 to 7 cm. Mean transformation efficiency of the GUS-gene marker was estimated at 350 transformants per 65 mg fresh weight of the maize cultured cells. Up to 200 GUS transformed cells were detected per 100 mg of embryogenic rice callus. Use of gold flakes or tungsten powder as microcarriers resulted in similar transformation rates. No transformation was observed in any cells when DNA constructs contained prokaryotic translation initiation sequences for the GUS gene. Based on transient GUS assays, further modification of the airgun device will likely be necessary to obtain high stable transformation rates.     

Atrogin-1/MAFbx,a Muscle-Specific Ubiquitin Ligase,Is Highly Expressed in the Smooth Muscle of the Chicken Gizzard

To improve the transformation efficiency of Zygosaccharomyces rouxii by electroporation, glycerol was added to the electroporation buffer and the cells were frozen at ?80 °C. These alterations drastically increased transformation efficiency, and we found that competent cells can be preserved at ?80 °C without decreasing their transformation efficiency for at least 30 d.     

Transformation of <Emphasis Type="Italic">Spirulina platensis </Emphasis>Strain C1 (<Emphasis Type="Italic">Arthrospira</Emphasis> sp. PCC9438) with Tn5 Transposase–Transposon DNA–Cation Liposome Complex

Spirulina platensis is one of the most commercially important species of microalgae. Thus, it is an attractive candidate for genetic manipulation and the development of novel practical applications. However, this process is hampered by the absence of a stable gene transfer system, specifically the limited number of suitable vectors and transformation methods available for this organism. Artificial transposon systems developed by extracting the essential elements from natural transposons have been extensively studied, and recently a mutated transposase and transposon system was reported to improve transformation efficiency by electroporation. We applied a modified transformation strategy using a natural Tn5 transposon, transposase, and cation liposome complex by electroporation to improve the transformation efficiency for Spirulina platensis strain C1 (Arthrospira sp. PCC9438). Aggregation of cells became visible after 3 weeks during 2.0 g/ml chloramphenicol selection, and growth continued for more than 12 months. Transfected chloramphenicol acetyltransferase (CAT) genes were detected in the genomic DNA by Southern hybridization. Transformed cells demonstrated CAT activity, but non-transformed cells did not.     

The myth of plant transformation

Technology development is innovative to many aspects of basic and applied plant transgenic science. Plant genetic engineering has opened new avenues to modify crops, and provided new solutions to solve specific needs. Development of procedures in cell biology to regenerate plants from single cells or organized tissue, and the discovery of novel techniques to transfer genes to plant cells provided the prerequisite for the practical use of genetic engineering in crop modification and improvement. Plant transformation technology has become an adaptable platform for cultivar improvement as well as for studying gene function in plants. This success represents the climax of years of efforts in tissue culture improvement, in transformation techniques and in genetic engineering. Plant transformation vectors and methodologies have been improved to increase the efficiency of transformation and to achieve stable expression of transgenes in plants. This review provides a comprehensive discussion of important issues related to plant transformation as well as advances made in transformation techniques during three decades.     

少量制备大肠杆菌感受态细胞条件探索

目的:为了获得重复性好、转化率高的少量制备感受态细胞的方法,利用不同生长时期的大肠杆菌感受态细胞,进行转化比较。方法:根据普通实验室的实验条件,常规方法提取质粒,氯化钙法转化不同生长时期的大肠杆菌感受态细胞,比较转化率。结果:大肠杆菌感受态细胞的转化率与OD值显著相关,在OD600nm为0.39和0.55时转化率最高,在OD600nm为0.28~0.55之间均可得到理想的转化效果。结论:少量制备感受态细胞方法操作中无需添加任何保护试剂和细胞复苏培养,操作简便、重复性好,实验成本低廉。     

大肠杆菌最佳感受态细胞制备的探讨

本文对４种大肠杆菌菌株在不同生长时期的转化效率分别进行了测定．结果表明,在细菌的生长繁殖过程中,其转化效率是有很大变化的．对于不同的菌株,它们获得高转化率时的活菌数不同．同时,得到了这４种大肠杆菌菌株制备最佳感受态细胞的条件．     

Agrobacterium-mediated transient GUS gene expression in buffel grass (Cenchrus ciliaris L.)

The study was conducted to standardize a protocol for Agrobacterium-mediated genetic transformation of buffel grass (Cenchrus ciliaris L.). Embryogenic calli, produced from one-year-old mature seeds of buffel grass, were used as target cells for Agrobacterium-mediated transformation. A. tumefaciens strain LBA4404, harbouring pCAMBIA-1301 or pCAMBIA-2301, was used for co-cultivation with embryogenic calli from three genotypes (IG-3108, IG-9757 and IG-97101). Co-culturing of calli with Agrobacterium for 30 minutes, followed by co-cultivation with 0.1 mM acetosyringone for 3 days was found to be optimum for maximum transformation efficiency. Presence of acetosyringone during co-cultivation was found to be necessary for transformation. Transient GUS (beta-glucuronidase) gene expression was used to monitor T-DNA delivery into the target cells. Significant genotypic variations in response to transformation were observed among the tested genotypes. A very high frequency (63.3%) of GUS gene expression was obtained following Agrobacterium-mediated gene transfer into embryogenic calli. The standardized protocol would be useful for Agrobacterium-mediated genetic transformation of buffel grass with genes of agronomic importance.     

Competence-induced cells of Streptococcus pneumoniae lyse competence-deficient cells of the same strain during cocultivation

Several streptococcal species are able to take up naked DNA from the environment and integrate it into their genomes by homologous recombination. This process is called natural transformation. In Streptococcus pneumoniae and related streptococcal species, competence for natural transformation is induced by a peptide pheromone through a quorum-sensing mechanism. Recently we showed that induction of the competent state initiates lysis and release of DNA from a subfraction of the bacterial population and that the efficiency of this process is influenced by cell density. Here we have further investigated the nature of this cell density-dependent release mechanism. Interestingly, we found that competence-induced pneumococci lysed competence-deficient cells of the same strain during cocultivation and that the efficiency of this heterolysis increased as the ratio of competent to noncompetent cells increased. Furthermore, our results indicate that the lysins made by competent pneumococci are not released into the growth medium. More likely, they are anchored to the surface of the competent cells by choline-binding domains and cause lysis of noncompetent pneumococci through cell-to-cell contact.