Protoplast

About: Protoplast is a research topic. Over the lifetime, 5474 publications have been published within this topic receiving 122468 citations.

Platelet-interactive products of Streptococcus sanguis protoplasts.

Abstract: To isolate a more native, platelet-interactive macromolecule (class II antigen) of Streptococcus sanguis, cultured protoplasts were used as a source. Protoplasts were optimally prepared from fresh washed cells by digestion with 80 U of mutanolysin per ml for 75 min at 37 degrees C while osmotically stabilized in 26% (wt/vol) raffinose. Osmotically stabilized forms were surrounded by a 9-nm bilaminar membrane, as shown by transmission electron microscopy. Protoplasts were cultured in chemically defined synthetic medium and osmotically stabilized by ammonium chloride. Spent culture media were harvested daily for 7 days. Each day, soluble proteins were isolated from media, preincubated with platelet-rich plasma, and tested for inhibition of platelet aggregation induced by S. sanguis cells. Products released from S. sanguis protoplasts and reactive with an anti-class II antigen immunoaffinity matrix were able to inhibit S. sanguis-induced platelet aggregation. As resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, anti-class II-reactive protoplast products included silver-stained bands of 67, 79, 115, 216, and 248 kDa. The 115-kDa protein fraction was isolated by gel filtration and ion-exchange chromatography. This form of the class II antigen contained N-formylmethionine at its amino terminus. Rhamnose constituted 18.2% of the total residual dry weight and nearly half of its carbohydrate content. Diester phosphorus constituted 1% of this fraction. After trypsinization of the protoplast products from either preparation, a 65-kDa protein fragment was recovered. This protoplast protein fragment and the S. sanguis cell-derived 65-kDa class II antigen, previously implicated in the induction of platelet aggregation, were shown to be functionally and immunologically identical.

Chapter 11 Protoplast Fusion and Somatic Hybridization

Abstract: Publisher Summary This chapter presents the results of somatic hybridization that are limited to model plants predominantly from the genera, Nicotiana, Petunia, Daucus , and Datura Several model systems are described in the chapter, which show that intra- and inter-specific flowering somatic hybrids can be obtained by protoplast fusion Such flowering somatic hybrids, in some cases, show the same genetic behavior as sexual hybrids Also, prezygotic ( P parodii + P inflata ) and embryo–endosperm (for example, D innoxia + D strumonium ) incompatibility can be overcome by protoplast fusion The regeneration of dihaploid and tetraploid protoplasts of S tuberosum is discussed in the chapter Potato is a crop plant that is extensively cultivated in the northern hemisphere Successful fusion experiments are carried out with potato and tomato, which demonstrates the applicability of this technique for potato A breeding scheme for potato is reviewed in the chapter that combines classical breeding methods with parthenogenetic and androgenetic induction of dihaploids and somatic hybridization

Tobacco protoplasts differentiate into elongate cells without net microtubule depolymerization

Abstract: Microtubules (MTs) are important for plant cell morphogenesis because they influence the deposition of cell plate and wall components. It has been observed that tobacco protoplasts contain a disordered MT array in the cortex. Following several days in culture, these protoplasts become elongate cells with an orderly cortical MT array. The transformation of the MT array may occur by net depolymerization of the disordered MTs and repolymerization of MTs into an ordered array, or by movement of the array as an integral unit. To experimentally distinguish between these two possibilities, the drug taxol was used to stabilize MTs. Protoplasts derived from suspension cultured tobacco,Nicotiana tabacum, were grown in a medium containing the two plant hormones α-naphthaleneacetic acid and benzyladenine, in the presence or absence of 10μM taxol. Changes in cell size and shape were quantified using a video image analysis system. Cell elongation had begun within 48h of protoplast conversion, in both treatments, and continued for 7 days. Immunolocalization of tubulin showed that, in the majority of cells, MTs were disorganized immediately following protoplast conversion. After elongation, the MT arrays were observed to have reoriented to an ordered state. Taxol-treated protoplasts were found to elongate faster and to a greater extent than the non-treated controls. Additionally, the cortical array of taxol-treated protoplasts reorganized more quickly. These data indicate that the net depolymerization of disordered cortical MTs is not necessarily required for the differentiation of a protoplast into an elongate cell.

Isolation of protoplasts from edible seaweeds

Abstract: Protoplasts were isolated enzymatically from three species of Chlorophyta (Enteromorpha linza, Monostroma zostericola andUlva pertusa) with high yield and viability. An enzyme solution appropriate for protoplast isolation from the marine green algae was the following: 2% Cellulase Onozuka R-10, 1.0.M mannitol, pH 6.0. Protoplasts could not be obtained from members of Phaeophyta or Rhodophyta.