Youn-Seb Shim scite author profile

SummaryNovel classes and applications of cell-penetrating peptides (CPPs) are being constantly discovered since they were first identified 2 decades ago. These short cationic peptides (nanomolecules) either by covalent binding or by noncovalent binding can traverse cell membranes and deliver a variety of molecules that are unable to overcome the permeability barrier in their own capacity. The ability of the CPPs to deliver variety of macromolecules, such as oligonucleotides, therapeutic drugs, proteins, and medical imaging agents, by forming nanoparticulate carriers in a range of cells has led them to emerge as a potential tool for both macromolecule delivery application and to gain insight into the fundamentals of mechanism of cellular uptake across the plasma membrane. This review explores the recent advances, challenges, and future prospects in the field of CPP-mediated cargo delivery in mammalian and plant cells. Studies have been conducted into the peptide chemistry and stability of CPP-macromolecular complexes. Most of the CPPs have been shown to be nontoxic and do not interfere with the functionality of the macromolecules delivered across the cell membrane. The mechanism of uptake of CPP-cargo complexes and the uptake of CPPs alone across the plasma membrane remains unresolved. As the world of CPPs is rapidly advancing in both mammalian and plant system, there is a promising future for the various applications of transduction and transfection into intact cells.

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Nuclear fusion leads to chromosome doubling during mannitol pretreatment of barley ( Hordeum vulgare L.) microspores

Kasha

Oro

et al. 2001

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A cytological study of barley microspores during pretreatment of the uninucleate stage to the early culture stage was conducted utilizing six genotypes. Among the three main pretreatments investigated, microspores completed the first mitotic division during 28 d cold pretreatment of spikes, with or without leaf sheath attached, and during 0.3 M mannitol pretreatment of anthers at 25 degrees C. However, during a 4 d pretreatment in 0.3 M mannitol at 4 degrees C this first mitotic division was blocked or delayed and subsequently most often occurred during the first day on culture medium. The first mitotic division of most microspores pretreated in 0.3 M mannitol was mostly symmetrical (55-60%), whereas it was asymmetric (94%) during the 28 d cold pretreatment of spikes. Following the first mitotic division during the mannitol pretreatment at 25 degrees C, closely associated daughter nuclei often appeared to fuse via membrane coalescence, leading to a high frequency of large uninucleate microspores. Based upon nuclear size, the frequencies of fused uninucleate microspores in genotypes GBC 778, GBC 777 and Igri were estimated to be 87%, 54% and 75%, respectively, after a 4 d mannitol pretreatment at 25 degrees C. Chromosome numbers in dividing nuclei and relative densitometry measurements of nuclear DNA in microspores from cv. Igri confirmed the apparent fused nature of large nuclei in uninucleate microspores. The high frequency of fused nuclei indicates that nuclear fusion occurred between both symmetric and asymmetric nuclei. Microspores of cv. Igri cultured on filter paper following three different pretreatments provided an average of about 12 000 embryo-like structures (ELS) per plate. In samples, 85-97% of these ELS regenerated green shoots. The frequency of doubled haploids (74-83%) following all pretreatments was similar to the frequencies of fused nuclei. The pretreatment of spikes in 0.3 M mannitol at 4 degrees C for 4 d is preferred as it appears to provide genotype independent induction and suspension of nuclear division, as well as regenerating green plants in a shorter time than cold alone.

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A Novel Method of Transgene Delivery into Triticale Plants Using the Agrobacterium Transferred DNA-Derived Nano-Complex

Ziemienowicz

Shim

Matsuoka

et al. 2012

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Genetic transformation of monocotyledonous plants still presents a challenge for plant biologists and biotechnologists because monocots are difficult to transform with Agrobacterium tumefaciens, whereas other transgenesis methods, such as gold particlemediated transformation, result in poor transgene expression because of integration of truncated DNA molecules. We developed a method of transgene delivery into monocots. This method relies on the use of an in vitro-prepared nano-complex consisting of transferred DNA, virulence protein D2, and recombination protein A delivered to triticale microspores with the help of a Tat 2 cell-penetrating peptide. We showed that this approach allowed for single transgene copy integration events and prevented degradation of delivered DNA, thus leading to the integration of intact copies of the transgene into the genome of triticale plants. This resulted in transgene expression in all transgenic plants regenerated from microspores transfected with the full transferred DNA/protein complex. This approach can easily substitute the bombardment technique currently used for monocots and will be highly valuable for plant biology and biotechnology.Transgenesis, or genetic transformation, finds many applications in plant biology, e.g. in cell biology and gene function studies. Importantly, it also allows for the generation of plants with improved agricultural traits significantly faster than any conventional breeding practice. The technology is based on the delivery of genes of interest from a broad range of sources into a plant genome. Two major transformation techniques include Agrobacterium-mediated DNA delivery and

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The relationship between induction of embryogenesis and chromosome doubling in microspore cultures

et al. 2006

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The objective of this paper is to review the relationship between induction of microspore embryogenesis and chromosome doubling. It has been augmented with relative data on chromosome doubling by nuclear fusion. Some of the treatments used for induction of embryogenesis may also lead to doubling of the chromosome number, either through nuclear fusion or endomitosis. High frequencies of spontaneous chromosome doubling in cereal species appear to be induced by treatments that block cell wall formation during the first cell divisions, resulting in coenocytic cells in which the nuclei are able to fuse. The use of mannitol as a pretreatment for induction of embryogenesis in barley, wheat, and maize microspore cultures provides examples of nuclear fusion. The use of antimicrotubule agents for embryo induction via treatments during the first few hours of microspore culture has also resulted in high frequencies of chromosome doubling. Factors such as the doubling agent concentration, temperature during treatment, and duration of treatment may be critical for individual species. Actin filament as well as microtubule assembly studies related to new cell wall formation provide further evidence at the molecular level for the relationship between microspore embryogenesis and chromosome doubling.

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Youn-Seb Shim

Cell‐penetrating peptides: Nanocarrier for macromolecule delivery in living cells

Nuclear fusion leads to chromosome doubling during mannitol pretreatment of barley ( Hordeum vulgare L.) microspores

A Novel Method of Transgene Delivery into Triticale Plants Using the Agrobacterium Transferred DNA-Derived Nano-Complex

The relationship between induction of embryogenesis and chromosome doubling in microspore cultures

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