Yona Tabib scite author profile

Plant regeneration and transformation in vitro is often improved by adding silver ion (Ag(+)) to the culture media as AgNO(3) or silver thiosulfate (STS). Ag(+) reacts with substances to form insoluble precipitates, while thiosulfate (S(2)O(3) (2-)) interferes with these reactions. We studied the implications of silver precipitation and S(2)O(3) (2-) in the medium for culture development by (1) examining formation of Ag(+) precipitates from AgNO(3) versus STS in agar gels and their possible dependence on agar type; (2) comparing Corymbia maculata culture responses to AgNO(3) and STS and determining which better suits control of culture development; (3) clarifying whether STS-dependent alterations in culture development are due to Ag(+) alone or also to a separate influence of S(2)O(3) (2-). Silver precipitates appeared in aqueous gels of four agar brands supplemented with AgNO(3), but not in Phytagel(™), which remained transparent. No precipitation was observed in gels with STS. Indole-3-butyric acid (IBA)-mediated adventitious root induction and shoot growth were higher in C. maculata shoot tips cultured on gels with STS versus AgNO(3) (6-25 μM Ag(+)). IBA-treated shoot tips exhibited enhanced adventitious root regeneration, accelerated root elongation, increased frequency of lateral root formation, and stimulated shoot growth mediated by 100-250 μM sodium thiosulfate (Na(2)S(2)O(3)) in medium without Ag(+). The potency of S(2)O(3) (2-) in facilitating culture development has never been recognized. It is inferred that superiority of STS in stimulating multiple responses of C. maculata culture results from sustained biological activity of Ag(+) through prevention of its precipitation, and from impact of S(2)O(3) (2-) on cell differentiation and growth.

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A simple plant regeneration-ability assay in a range of Lycopersicon species

Steinitz

Amitay

Gaba

et al. 2006

Plant Cell Tiss Organ Cult

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Plant growth regulator-dependent (PGR-dependent) in vitro shoot organogenesis has been extensively studied in tomato (Lycopersicon esculentum), whereas PGR-independent adventitious shoot organogenesis received marginal attention in L. esculentum and no consideration at all in other Lycopersicon species. In the present study, induction of PGR-independent adventitious shoots was by decapitation of the apex and removal of preexisting shoot meristems of the seedling, and seedling culture on a medium with no PGR supplements. The existence of PGR-independent regeneration-ability was verified in L. esculentum genotypes (high pigment photomorphogenic mutants and wild-type counterparts) and was uncover amongst L. cheesmanii, L. chilense, L. chmielewskii, L. hirsutum, L. parviflorum, L. peruvianum and L. pimpinellifolium. Compared to species other than L. esculentum, high pigment photomorphogenic mutants displayed the weakest PGR-independent regeneration-ability. Our results imply that decapitated seedlings cultured on a medium without PGRs can serve as a convenient assay system for genotypic variation in self-controlled, PGR-independent, shoot regeneration-ability in a wide range of Lycopersicon species. Using transverse thin slices of the hypocotyl placed onto a medium supplemented with 0.2 lM zeatin reboside and 0.04 lM IAA, we assessed PGR-mediated shoot regeneration in L. esculentum genotypes. In a given genotype, more plants per seedling were established by PGR-mediated than by PGR-independent regeneration. However, with both modes of organogenesis, only a fraction of shoot buds eventually grew into normal plants, while others developed into abnormal regenerants having no stem. Percentage of stem-deficiency, in a given genotype, was higher in PGR-treated cultures, which indicates that PGRs amplify the formation frequency of imperfect adventitious apical shoot meristems. Unlike L. esculentum, adventitious shoot buds of other Lycopersicon species, induced by wounding seedlings that were not treated with PGRs, rarely formed regenerants lacking a stem.Abbreviations: IAA -indole-3-acetic acid; IBA -indole-3-butyric acid; MES -2-(N-morpholino)ethanesulfonic acid; PGR -plant growth regulator; RIM -root induction medium; SIM -shoot induction medium; ZR -zeatin riboside

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Vegetative micro-cloning to sustain biodiversity of threatened Moringa species

Steinitz

Tabib

Gaba

et al. 2008

In Vitro Cell.Dev.Biol.-Plant

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Efficient vegetative cloning in vitro requires definition of plant growth regulator regimes for each genotype, and therefore formulation of a uniform culture protocol for a genetically heterogeneous wild or uncultivated plant population is often impossible. The likelihood of cloning a wide array of plant genotypes by avoiding the use of plant growth regulator(s) was explored with Moringa oleifera Lamk., Moringa stenopetala (Baker f.) Cufod, and Moringa peregrina Forssk. ex Fiori tree seedlings. Propagation was achieved by multiple shoot regeneration from the cotyledonary node of decapitated seedlings, followed by axillary shoot growth from single node shoot segments and rooting of excised shoots. All steps were accomplished on basal Murashige and Skoog medium without plant growth regulator supplements. The results revealed competence for generation of multiple shoots from cotyledonary node tissue, stimulated by repeated shoot harvest, in seedlings of all three tree species. Tens of plants per seedling were regenerated in about 4 mo from culture initiation. In a given species clone size was seedling-dependent, which presumably stems from genotypic variability among seedlings in regeneration ability in vitro. By this means the laborious search for a plant growth regulator regime suitable for organogenesis induction and adapted per genotype became redundant, and biodiversity of the seed germplasm could be maintained. The approach ideally suits establishment of clones of wild plants of endangered species, like those of the Moringaceae, species with high ability for producing supplementary shoots, and without the need to add plant growth regulators, including the rooting stage.

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An intact F 1 ATPase ⋅-subunit gene and a pseudogene with differing genomic organization are detected in both male-fertile and CMS petunia mitochondria

Yesodi¹,

Hauschner²,

Tabib³

et al. 1997

Current Genetics

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The gene copies for the alpha-subunit of the mitochondrial F1ATPase (atpA) were isolated and characterized in both male-fertile and cytoplasmic male sterile (CMS) petunia. Two copies, an intact gene and a truncated gene, were detected in both cytoplasms. The accumulated data, based upon a comparison of the sequences (the open reading frames as well as the 5' and 3' flanking regions) of the two atpA copies, both in male-fertile and CMS Petunia, indicate that: (1) they differ in their genomic organization and (2) a common progenitor cytoplasm, containing two copies of an intact atpA sequence, served as the origin for the atpA copies of the fertility and CMS-inducing cytoplasms. Homologous recombination through the progenitor intact atpA sequences is assumed to have caused the rearrangement in the 3' portion of the atpA open reading frame and the generation of the truncated atpA gene. It is thus suggested that the atpA pseudogenes, in both male-fertile and CMS cytoplasms, originated from a common progenitor atpA pseudogene sequence.

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Yona Tabib

Pepper (capsicum annuum L.) regenerants obtained by direct somatic embryogenesis fail to develop a shoot

Control of in vitro rooting and plant development in Corymbia maculata by silver nitrate, silver thiosulfate and thiosulfate ion

A simple plant regeneration-ability assay in a range of Lycopersicon species

Vegetative micro-cloning to sustain biodiversity of threatened Moringa species

An intact F 1 ATPase ⋅-subunit gene and a pseudogene with differing genomic organization are detected in both male-fertile and CMS petunia mitochondria

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