An efficient protocol for transient transformation of intact fruit and transgene expression inCitrus

In this study, conditions were optimized for transient gene expression in Rough Lemon (Citrus jambhiri Lush.), a major rootstock used in the citrus growing regions of Pakistan.Agrobacterium tumefaciens carrying the binary vector p35GUSINT, containingNPT II andGUS genes, was used in the study. The transformation method was based on injection ofAgrobacterium intoCitrus fruits followed by histochemical assay ofGUS activity in different tissues. Different tissues of mature fruits exhibited significantly different percentages of transientGUS expression: in rind (76%), spongy tissue (92%), juice vesicles (0%) and seeds (83%) (P<0.01)., The incubation period after injecting theAgrobacterium culture also showed a significant (P<0.01) effect on the transient expression ofGUS in these tissues. An incubation period of 48 h was found to be the best (72%) for transformation of whole fruit, followed by 72 h (67%) and 96 h (49%). TransientGUS expression also varied significantly (P<0.01) in juice vesicles and seeds as fruit matured. Juice vesicles from mature fruits showed no transientGUS expression, while those from immature fruits showed 50% expression. Furthermore, transformation of seeds had no effect on their germination capability. Germinating seeds from mature fruits injected withAgrobacterium culture showed tolerance to kanamycin (100 mg/L), which varied with the incubation period (55% at 48 h, 25% at 72 h and 23% at 96 h). This report offers an easy protocol for transient expression studies of transgenes and has the potential to be used for stable transformation ofCitrus.     

Establishment of compartments in the developing leg imaginal discs ofDrosophila melanogaster

Summary By X-irradiation ofM/M ⁺ embryos and larvae to induce mitotic recombination, clones ofM ⁺/M⁺ genotype were obtained (Fig. 1). Since such cells grow faster than the surroundingM/M ⁺-cells they can fill large areas within the compartments of an imaginal disc.The present studies concentrated mainly on the three leg discs. Clones were induced by doses of 1000 r at ages ranging from 3±0.5 h after oviposition to 144 h.All clones induced later than the blastoderm stage were absolutely restricted to either the anterior or the posterior compartment of a disc. The border between the anterior and posterior compartment runs as a straight line along the entire leg and at the distal end separates the two claws (Figs. 5, 6, 7). A further subdivision of the anterior compartment is indicated by clones initiated in the second larval instar (Fig. 11). A parallel subdivision could not be detected in the posterior compartment. Irradiation in the early third instar led to clones which were restricted to single longitudinal bristle rows and leg segments. But no clear-cut compartment borders could be found; in particular a proximo-distal separation appears to be absent.Among the 318 clones induced at the blastoderm stage eleven extended from the wing into the second leg (Fig. 8), or from the haltere into the third leg.With the exception of 3 clones that apparently occupied the anterior as well as the posterior compartment of a wing or a leg, all clones remained confined to either the anterior or the posterior compartment.Frequently clones overlapped left and right forelegs (Fig. 9). Intersegmental overlaps were not observed.The results show that the earliest compartment borders appear in all thoracic discs. This suggests that compartmentalization is a fundamental process common to all discs.Supported bySchweizerischer Nationalfonds Gesuch Nr. 3.480-0.75     

Genetic studies of mutations at two loci of Drosophila melanogaster which cause a wide variety of homeotic transformations

Summary The ash-1 locus is in the proximal region of the left arm of the third chromosome of Drosophila melanogaster and the ash-2 locus is in the distal region of the right arm of the third chromosome. Mutations at either locus can cause homeotic transformations of the antenna to leg, proboscis to leg and/or antenna, dorsal prothorax to wing, first and third leg to second leg, haltere to wing, and genitalia to leg and/or antenna. Mutations at the ash-1 locus cause, in addition, transformations of the posterior wing and second leg to anterior wing and second leg, respectively. A similar spectrum of transformations is caused by mutations at yet another third chromosome locus, trithorax. One extraordinary aspect of mutations at all three of these loci is that they cause such a wide variety of transformations. For mutations at both of the loci that we have studied the expression of the homeotic phenotype is both disc-autonomous (as shown by injecting mutant discs into metamorphosing larvae) and cell autonomous (as shown by somatic recombination analysis). The original mutations which identified these two loci, although lethal, manifest variable expressivity and incomplete penetrance of the homeotic phenotype suggesting that they are hypomorphic. The phenotype of double mutants which were synthesized by combining different pairs of those original mutations manifest for two of the four pairs a greater degree of expressivity and slightly more penetrance of the homeotic transformations. This mutual enhancement suggests that the products of both loci interact in the same process. A third double mutant expresses a discless phenotype.Additional alleles have been recovered at both the ash-1 and the ash-2 loci. Some of these alleles as homozygotes or transheterozygotes express the wide range of transformations revealed first by double mutants. One of the alleles at the ash-1 locus when homozygous and several transheterozygous pairs can cause either the homeotic transformation of discs or the absence of those discs. The fact that these two defects, absence of specific discs and homeotic transformations of those same discs can be caused by mutations within a single gene suggests that the activity of the product of this gene is essential for normal imaginal disc cell proliferation. Loss of that activity leads to the absence of discs, whereas, reduction of that activity leads to homeotic transformations.     

TheUbx syndrome ofDrosophila: the prothoracic transformation (ppx) is independent ofbx,bxd andpbx

Summary If, early in development, theUbx ⁺ gene is removed by mitotic recombination from cells of the meso-and metathoracic leg primordia, theseUbx ^– cells develop as in the posterior prothoracic leg. We show that this transformation, termedpostprothorax, is a discrete genetic function that is independent of other homeotic transformations such asbx, pbx orbxd, which also result from the inactivation of theUbx gene.     

Transdetermination in leg imaginal discs ofDrosophila melanogaster undDrosophila nigromelanica

Summary The transdetermination capacities of leg discs ofDrosophila melanogaster were examined by mechanically disrupting and kneading whole discs from late third instar larvae and by culturing the resulting tissue mass for 10–14 days in adult female abdomens where the cells continued to divide. The grown implants were then dissected from the abdomens and injected into third instar larvae to undergo metamorphosis.After this treatment, prothoracic leg discs ofDrosophila melanogaster transdetermined with a high frequency (59% of all implants) to wing. Mesothoracic leg discs also transdetermined to wing, but at a very low frequency (4%). Metathoracic leg discs exhibited the same low frequency of transdetermination (4%), but in this case the direction of transdetermination was to haltere (Table 1,D. melanogaster).Very similar results were obtained with leg discs ofDrosophila nigromelanica (Table 1,D. nigromelanica), showing that the peculiar behavior of the three leg discs is not unique forDrosophila melanogaster.The homeotic mutation Polycomb (Pc ³) which partially transforms meso- and metathoracic legs into prothoracic legs did not significantly increase the frequencies of transdetermination in these leg dises and had clearly no effect on the direction of transdetermination (Table 1).We dedicate this publication to the memory of our teacher and advisor, the late Professor Ernst Hadorn, whose enthusiasm and interest stimulated our work     

Direct control of antennal identity by the spineless-aristapedia gene of Drosophila

Summary Loss-of-function mutations in the spineless-aristapedia gene of Drosophila (ss ^a mutants) cause transformations of the distal antenna to distal second leg, deletions or fusions of the tarsi from all three legs, a general reduction in bristle size, and sterility. Because ss ^a mutants are pleiotropic, it has been suggested that ss ⁺ has some rather general function and that the ss ^a antennal transformation is an indirect consequence of perturbations in the expression of other genes that more directly control antennal or second leg identity. Here we test whether the ss ^a transformation results from aberrant expression of Antennapedia (Antp), a homeotic gene thought to specify directly the identity of the second thoracic segment. We find that Antp ^– ss ^a mitotic recombination clones in the distal antenna behave identically to Antp ⁺ ss ^a clones, and are transformed to second leg. This demonstrates that the ss ^a antennal transformation is independent of Antp ⁺, and suggests that ss ⁺ may itself directly define distal antennal identity. The results also reveal that Antp ⁺ is not required for the development of distal second leg structures, as these develop apparently normally in Antp ^– ss ^a antennal clones. Because Antp ^– mutations cause deletions or transformations that are restricted to proximal structures, whereas ss ^a alleles cause similar defects that are distally restricted, we suggest that ss ⁺ and Antp ⁺ may play similar, but complementary, roles in the distal and proximal portions of appendages, respectively.     

Role of the host cell cycle in theAgrobacterium-mediated genetic transformation ofPetunia: Evidence of an S-phase control mechanism for T-DNA transfer

Chimeric -glucuronidase (GUS) gene expression in an efficientAgrobacterium-mediated transformation system utilising mesophyll cells ofPetunia hybrida synchronized with cell cycle phase-specific inhibitors (mimosine and colchicine) was used to show the absolute requirement of S-phase for transfer and/or integration of the transferred DNA (T-DNA). Flow-cytometric analysis of nuclear DNA content and immunohistological detection of bromodeoxyuridine (BrdUrd) incorporation showed that, prior to phytohormone treatment, most (98%) mesophyll cells were at GO-Gl-phase (quiescent phase) and no cell division was occurring. After 48 h and 72 h of phytohormone treatment, there was a rapid increase in S-G2-M-phase populations (> 75%) and a concomitant decrease (down to 24%) in G0–-G1-phase cells. Assays of GUS showed that maximum transformation (> 95% of explants) also occurred after this period. Our data showed that mimosine and colchicine blocked the mesophyll cells at late Gl-phase and M-phase, respectively. No transformation (= GUS expression) was observed in phytohormone-treated cells inhibited in late G1 by mimosine. However, after removal of mimosine, 82% of the explants were transformed, indicating the non-toxic and reversible effect of the inhibitor. On the other hand, a relatively high transformation frequency (65% of explants) was observed after blocking the cell cycle at M-phase with colchicine. However, only transient, but no stable, gene expression (= kanamycin-resistant callus formation) was observed in colchicine-treated M-phase-arrested cells. Similarly, endoreduplication of nuclear DNA, which occurred during the 48 h of phytohormone treatment in some mesophyll cells and cells located along the minor veins in the leaf explants, resulted in transient GUS expression only. These observations indicate a direct correlation between endoreduplication and transient GUS gene expression. Obviously, for stable GUS gene expression, cell division and proliferation are required, indicating that both DNA duplication (S-phase) and cell division (M-phase) are strongly related to stable transformation. We propose that the present system should facilitate further dissection of the process of T-DNA integration in the host genome and therefore should aid in developing new strategies for transformation of recalcitrant plants.Abbreviations BAP 6-benzylaminopurine - BM basal medium - BrdUrd bromodeoxyuridine - GUS -glucuronidase - Km^R kanamycin resistant - T-DNA transferred DNA     

A p53 mutation is required for stable transformation of REF52 cells by themyc andras oncogenes

It is known that neoplastic transformation of rodent primary embryonic fibroblasts culturedin vitro requires coexpression at least of two cooperating oncogenes. In the case of transduction into cells of oncogenesras andmyc, the cell transformation is poorly effective. To study some additional factors necessary for such transformation, c-myc and N-ras ^Asp12 were consecutively introduced into REF52 cells by retroviral infection, and the cell cultures obtained were analyzed. Expression ofmyc broke the regulation of the cell cycle, in particular, canceled the G1 phase arrest for cells with damaged DNA, despite the normal function of protein p53 and induction of the p53-responsive genep21 ^Waf1 in these cells. The subsequent transduction ofras led to morphological transformation of cells and an increase of p53 level. However, reversion of the transformed phenotype to normal morphology took place after less than five passages. On this background, rare clones generated the stable transformed cell lines characterized by accelerated proliferation and having a mutation in thep53 gene. Attempts to obtain stable transformed cell lines by transduction ofras into REF52 cells not expressing exogenousmyc were unsuccessful. Analysis of the stable transformed clones revealed a mutation at codon 271 of thep53 gene, a hot spot of mutations, which led to the replacement of arginine by cysteine. In these clones, p53 is accumulated owing to the increased life time, and has a flexible conformation, being able to interact with monoclonal PAb1620 and PAb240 antibodies recognizing alternative protein conformations. The results obtained suggest that p53 participates in negative regulation of the cell cycle under conditions of oncogenic stimulation, and its inactivation is necessary for full transformation of cells by cooperating oncogenesmyc andras.     

Suppression of abdominal legs inDrosophila melanogaster

Summary Drosophila melanogaster normally have six thoracic legs and no abdominal legs. However, one or two legs often appear in the first abdominal segment ofbithoraxoid mutants. The extent to which these extra legs develop is determined both by thecis-regulatory action ofbithoraxoid lesions onUltrabithorax and by the number of copies of the adjacent homeotic geneabdominal-A. Thebithoraxoid region does notcis-regulateabdominal-A.     

The effect of temperature onshibire ts cell clones in the compound eye ofDrosophila melanogaster

Summary We have analysed the effect of temperature on both developing and adult eye cell clones homozygous forshi ^ST139, a temperature-sensitive mutant ofDrosophila melanogaster. The mutant gene, autonomous in its cellular expression, causes structural modifications of ommatidial cells when adult clones of cells are exposed to the restrictive temperature (29°C) for several days. However, the mutant phenotype reverses to normal within 4 days at the permissive temperature (20°C). The results of pulse, shift-up and shift-down experiments show that the temperaturesensitive period for developing compound eye cells is from the late second instar up to the early pupa. Cytodifferentiation of compound eye cells is blocked by restrictive temperature treatment during this period, whereas cell proliferation does not seem to be directly affected. These results are discussed with regard to the other known aspects of the phenotype observed in mutant individuals.     

Genetic complementation of a floral homeotic mutation,apetala3, with an Arabidopsis thaliana gene homologous to DEFICIENS of Antirrhinum majus

Among the homeotic mutants with altered floral organs, two mutants of Arabidopsis thaliana, apetala3 and pistillata, and two mutants of Antirrhinum majus, deficiens and globosa, have a homeotic conversion of the floral organs in whorl 2 and 3, namely petals to sepals and stamens to carpels. We have isolated a homologue of the DEFICIENS gene from A. thaliana wild type and shown complete complementation of apetala3 mutation by introducing the isolated gene using Agrobacterium-mediated transformation. These results show that the APETALA3 is a homologue of DEFICIENS structurally and functionally. The 5-upstream region of APETALA3 contains three SRE-like sequence, where MADS box-containing proteins are assumed to bind and regulate expression in tissue-and stage-specific manner.     

Spatial and temporal regulation of the homeotic selector gene Antennapedia is required for the establishment of leg identity in Drosophila

Antennapedia is one of the homeotic selector genes required for specification of segment identity in Drosophila. Dominant mutations that ectopically express Antennapedia cause transformation of antenna to leg. Loss-of-function mutations cause partial transformation of leg to antenna. Here we examine the role of Antennapedia in the establishment of leg identity in light of recent advances in our understanding of antennal development. In Antennapedia mutant clones in the leg disc, Homothorax and Distal-less are coexpressed and act via spineless to transform proximal femur to antenna. Antennapedia is negatively regulated during leg development by Distal-less, spineless, and dachshund and this reduced Antennapedia expression is needed for the proper development of distal leg elements. These findings suggest that the temporal and spatial regulation of the homeotic selector gene Antennapedia in the leg disc is necessary for normal leg development in Drosophila.     

Specification of Primary Pigment Cell and Outer Photoreceptor Fates byBarH1Homeobox Gene in the DevelopingDrosophilaEye

In the developingDrosophilaeye,BarH1andBarH2, paired homeobox genes expressed in R1/R6 outer photoreceptors and primary pigment cells, are essential for normal eye morphogenesis. Here, we show evidence thatBarH1ectopically expressed under the control of thesevenlessenhancer (sev-BarH1) causes two types of cone cell transformation: transformation of anterior/posterior cone cells into outer photoreceptors and transformation of equatorial/polar cone cells into primary pigment cells.sev-BarH1repressed the endogenous expression of theroughhomeobox gene in R3/R4 photoreceptors, while theBarH2homeobox gene was activated bysev-BarH1in an appreciable fraction of extra outer photoreceptors. In primary pigment cells generated by cone cell transformation, the expression ofcut,a homeobox gene specific to cone cells, was completely replaced with that ofBarhomeobox genes. Extra outer photoreceptor formation was suppressed and enhanced, respectively, by reducing the activity of Ras/MAPK signaling and by dosage reduction ofyan,a negative regulator of the pathway, suggesting interactions betweenBarhomeobox genes (cell fate determinants) and Ras/MAPK signaling in eye development.     

Negative regulation ofUltrabithorax expression byengrailed is required for proper specification of wing development inDrosophila melanogaster

In both vertebrates and invertebrates, homeotic selector genes confer morphological differences along the antero-posterior axis. However, insect wing development is independent of all homeotic gene functions, reflecting the ground plan of an ancestral pterygote, which bore wings on all segments. Dipteran insects such asDrosophila are characterized by a pair of wings in the mesothoracic segment. In all other segments, wing development is essentially repressed by different homeotic genes, although in the metathorax they are modified into a pair of halteres. This necessitates that during development all homeotic genes are to be maintained in a repressed state in wing imaginal discs. In this report we show that (i) the function of the segment polarity geneengrailed (en) is critical to keep the homeotic selector geneUltrabithorax (Ubx) repressed in wing imaginal discs, (ii) normal levels of En in the posterior compartment of haltere discs, however, are not enough to completely repressUbx, and (iii) the repression ofUbx byen is independent of Hedgehog signalling through which the long-range signalling ofen is mediated during wing development. Finally we provide evidence for a possible mechanism by whichen repressesUbx. On the basis of these results we propose thaten has acquired two independent functions during the evolution of dorsal appendages. In addition to its well-known function of conferring posterior fate and inducing long-range signalling to pattern the developing appendages, it maintains wing fate by keepingUbx repressed.     

重金属超富集植物东南景天毛状根的诱导

为建立重金属超富集植物东南景天(Sedum alfredii)的毛状根诱导体系,采用发根农杆菌(Agrobacterium rhizogenes)A4侵染叶片,研究了预培养时间、侵染时间和共培养时间对毛状根诱导率的影响。结果表明,东南景天叶片外植体的预培养时间为48 h、农杆菌侵染时间为6 min、共培养时间为48 h是适宜的毛状根诱导时间,毛状根的诱导率可达85%。PCR检测表明诱导的毛状根中存在rol B基因片段。这是东南景天首次建立用发根农杆菌诱导毛状根体系。     

The use of cytoplasmic streptomycin resistance: Chloroplast transfer from Nicotiana tabacum into Nicotiana sylvestris, and Isolation of their somatic hybrids

Summary Leaf protoplasts of Nicotiana tabacum SR1 (2n=4x=48) treated with iodoacetate (10 mM; 25 C; 30 min) and consequently unable to divide, and untreated leaf protoplasts of Nicotiana sylvestris (2n=2x=24) were fused using polyethylene glycol (PEG). The SR1 line is resistant to streptomycin because of a maternally inherited mutation, and has streptomycin-insensitive chloroplast ribosomes.After 1 month of growth in the absence of streptomycin protoplast-derived calli were plated into selective medium (1,000 g ml^-1 streptomycin) and the resistant clones were isolated. Out of 10⁶ PEG-treated protoplasts (1:1 mixture of parental types) 137 resistant (green) clones were obtained, whereas in the same number of parental cells, not subjected to fusion induction, no resistant callus was found.At least four plants were regenerated from each of the clones. The regenerates were identified as somatic hybrids (H), N. sylvestris (Ns) or N. tabacum (Nt) by looking at esterase and peroxidase isoenzymes and morphology. The three types of regenerates were distributed amongst the clones as follows: H only (105 clones); Ns (16 clones); Ns+H (6 clones); Nt only (3 clones); Nt+H (6 clones); Nt+Ns (1 clone). The high proportion of hybrid regenerates indicates that nuclear fusion has occured in the overwhelming majority of the heterokaryocytes. Cytoplasmic mutations in combination with inactivation by iodoacetate, therefore, are suitable markers to produce somatic hybrids. Segregation of nuclei after fusion resulted in new combinations of organelles and nuclei, the final outcome being the transfer of resistant chloroplasts into N. sylvestris, some of which have the original diploid (2n=24) chromosome number. Data suggest that segregants were in most cases obtained from multiple fusions. Streptomycin resistance was inherited maternally in the N. sylvestris (six clones) tested and the hybrid (three clones) regenerates.     

Genetic transformation of Populus nigra by Agrobacterium tumefaciens

Two clones of Populus nigra L. were tested in vivo and in vitro for their susceptibility to three different Agrobacterium tumefaciens wild-type strains evaluating number and size of resulting calluses. Strain C58 proved to be the most virulent.Various parameters affecting Agrobacterium-mediated transformation of P. nigra clones were further analyzed using ß-glucuronidase gene transient expression. The clone Jean Pourtet proved to be more susceptible than the clone San Giorgio. A. tumefaciens strain A281 pKIWI105 proved to be the most virulent. The optimal procedure involved dipping of leaf discs into a bacterial suspension (7×10⁸ cells/ml) for 20 min, followed by a 48 h co-cultivation period on semi-solid regeneration medium.Leaf explants were co-cultivated with two disarmed A. tumefaciens strains. Plantlets of San Giorgio were regenerated, tested for ß-glucuronidase activity and rooted on selective medium containing kanamycin. Polymerase chain reaction analysis and Southern blot hybridization confirmed the integration of the neomycin phosphotransferase II gene into the poplar genome.Abbreviations BAP 6-benzyl-aminopurine - CaMV Cauliflower Mosaic Virus - 2,4-D 2,4-dichlorophenoxyacetic acid - GUS and gus ß-glucuronidase - hpt hygromycin phosphotransferase - IBA indole-3-butyric acid - KIN kinetin - LB Luria Bertani - MS Murashige and Skoog - NAA ßnaphthaleneacetic acid - NOS Nopaline synthase - NPTII and nptII neomycin phosphotransferase II - PCR Polymerase chain reaction - PVC poly-vinyl-cloride - SDS sodium dodecyl sulfate - SSC sodium cloride-sodium citrate - Tris tris(hydroxymethyl)amino-methane - WPM Woody Plant Medium     

Bristle patterns and clones along a compartment border in the anterior wing margin ofDrosophila hydei

Summary The bristle pattern along the first longitudinal vein of the wing ofD. hydei differs from that ofD. melanogaster. Instead of a triple row,D. hydei and some allied species show a pattern of five parallel bristle rows of which the medial row (MR) is comparable to the medial triple row (MTR) ofD. melanogaster. Cells of the MR can be made homozygousyellow (y) by induction of mitotic recombination in heterozygousy/y ⁺ females. Until 70 h after egg laying (AEL), the MR clones inD. hydei overlap with one or more of the accompanying dorsal and ventral bristle rows. Between 70 and 120 h AEL the MR clones only overlap with dorsal bristle rows. Some time later they also become separated from both dorsal rows. The resulting MR clone pattern fits with the overall longitudinal clone pattern in the wing blade ofD. melanogaster described by Bryant (1970) and others. The MR clones inD. hydei, however, often show a fragmented appearance with many indentations of the surroundingy ⁺ tissue even when induced after fixation of the DV compartment boundary. This result contrasts with the commonly held notion, derived from work withD. melanogaster, that compartment boundaries are smooth lines.     

A temperature sensitive mutation that reduces mitotic rate inDrosophila melanogaster

Summary A temperature-sensitive cell autonomous mutation ofDrosophila, l(1)ts-1126 (1–16±2), that affects the rate of cell division is described. When mutant animals are exposed to the restrictive temperature of 29°C during the first and second larval stages, the growth rate of the larvae is retarded. A delay in pupariation occurs during which larvae reach their full size, and the resulting flies are normal. When mutant animals are exposed to restrictive temperature during the third larval stage, growth is also retarded but no delay in pupariation occurs, and the resulting flies are reduced in size. Their small size is due in part to a decreased number of cells and in part to a smaller size of the cells.X-ray induced, marked, homozygousl(1)ts-1126 clones in an otherwise normal animal, are smaller in animals exposed to pulses of restrictive temperature when compared to clones in animals kept at permissive temperature of 22°C. Clone size decreases as pulse length increases. Clones on the wing blade induced 24 h after oviposition are smaller than clones induced at 48 h in animals grown at restrictive temperature. This result is interpreted as an inability of the slower dividingl(1)ts-1126 cells to survive when in competition with wildtype cells. The distribution of survivingl(1)ts-1126 clones in gynandromorphs grown at restrictive temperature supports this conclusion.