• Applied Microscopy
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• v.34 no.4
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• pp.295-303
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• 2004

Plants of Lycopersicon esculentum, containing various organic compounds, are known to develop idioblasts in their epidermis. Lycopersicon esculentum have long been investigated in many areas, but structural aspects of the epidermis of various organs have not been carried out in detail. Thus, the present study attempted to reveal the patterns of idioblast development, particularly those of the reproductive organs, in L. esculentum epidermis using scanning electron microscopy. The present study mainly focused on patterns of the stomata and trichome types. Two types of stomata were developed in the flowers and fruits: anomocytic stomata (stomata type I) were distributed normally throughout the epidermis, whereas actinocytic raised stomata (stomata type II) were found variously in different epidermal tissues. For the trichomes, both glandular and non-glandular types were developed in the epidermis. The former included peltate glandular trichomes having four head cells (trichome type I) and capitate multicellular glandular trichomes (trichome type II). The latter included non-glandular short trichomes (trichome type III) and considerably elongated trichomes with basal rosette cells (trichome type IV). In paticular, the raised stomata were well-developed in the peduncles and the peltate glandular trichomes were prominent in the sepal and ovary epidermis. Transmission electron microscopy on the ontogeny and ultrastructural differentiation of these idioblasts, associated with the current result, will aid us in better understanding of the structure and functional relationship in the epidermal differentriation of Lycopersicon esculentum.

• Applied Microscopy
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• v.40 no.4
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• pp.237-244
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• 2010

Utricularia forms small, but complex carnivorous trap along the stem either in water or in soil depending upon species. The shapes and sizes of the traps, appendages, and trichomes are known to differ among aquatic, terrestrial and epiphytic species. In the present study, the morphology and microstructure of the trap in aquatic Utricularia japonica and terrestrial U. livida were examined using light and electron microscopy. The aim of this study was to compare the characteristics of trap features between the aquatic and terrestrial species. The trap was found to be comprised of a thin walled bladder with numerous capitate trichomes, two-armed bifid and four-armed quadrifid glands in both species; however, the traps of the two species were different in size, and number and morphology of the trichomes and glands. Aquatic Utricularia was chlorenchymatous with chloroplasts distributed throughout the body, whereas the terrestrial species was translucent without plastids due to an adaptation to underground habitats. Furthermore, the former differed considerably in that the traps developed antenna and appendages around the entrance area. A peculiar trap entrance was also noted in U. livida, which exhibited radiating rows of various trichomes within funnel-shaped tissue. A large number of glandular trichomes covered the entrance area and door surface with four trigger hairs each in the aquatic form but only two in the terrestrial form. The glandular trichomes near the door secreted a large amount of mucilage that temporarily composed the velum in the U. japonica, however, it was not observed in the terrestrial species. All of the aforementioned features were highly related in their structure and function during carnivorous mechanism in Utricularia. The current findings provide important data for further comparison of the different life forms within Utricularia.

• Applied Microscopy
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• v.40 no.2
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• pp.101-108
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• 2010

Vitex negundo is an aromatic plant which releases a unique scent due to the presence of essential oil stored presumably within glandular trichomes. The focus of this research was to study developmental patterns of glandular trichomes in Vitex negundo leaves using electron microscopy. There are two types of glandular trichomes which develop on the leaf epidermis of Vitex negundo, peltate glandular type (PT) and capitate glandular type (CT). Structural features differ significantly depending on size and density, formation of secretory cavity, plastid, etc during developmental stages. In young leaves, undifferentiated PTs are densely distributed in the upper epidermis, but are not externally exposed in the lower epidermis because they are covered by non-glandular simple trichomes. Upon leaf development, PTs and CTs show clear structural differentiation in the upper and lower epidermis. PTs are composed of up to eight head cells (ca. 35~40 ${\mu}m$) and one stalk cell (ca. 5 ${\mu}m$), while CTs are composed of four head cells (ca. 10~15 ${\mu}m$) and 1~2 stalk cells (ca. 10 ${\mu}m$). Although secretory cavities develop on the secretory head cells, their size, structure, and formation proceed very differently depending on trichome type. In early development of PT, a large cavity with numerous secretory vesicles form rapidly from the head cells. In CT, however, only a small secretory cavity is formed, slowly relative to PT, without secretory vesicles. The PTs are considered to play an important role in releasing the aromatic components of Vitex negundo.

• Applied Microscopy
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• v.36 no.1
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• pp.35-45
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• 2006

Plants of Vitex negundo are known to develop numerous trichomes throughout their body, where certain trichome types have been believed to be one of the plausible structures for the unique scents. In the current study. structural aspects of the trichomes have been examined in leaves and stems of Vitex negundo using TEM and SEM. Trichome types as well as structural changes that occurred in certain trichomes during secretion have been mainly focused. Three type of glandular trichomes and two types of non-glandular trichomes were developed in the epidermis of young and mature Vitex negundo plants. The glandular trichomes included the peltate type (Type 1), the capitate type (Type 2), and degraded capitate type (Type 3), whereas the non-glandular warty trichomes contained the multicellular (Types 4) and unicellular type (Type 5). Type 1 and 2 consisted of head and stalk cells, but their number and size were different. One secretory cavity was formed from the four head cells in the former, but only two head cells were involved in the latter. The cytoplasmic density in the head cell was quite high and in particular, sER and Golgi bodies were well developed. At initiation of their development, the cuticle layer of the head cells separated from the outer tangential wall to form a secretory cavity. Subsequently the cavity expanded acropetally and a large number of secretory vesicles continuously produced from the head cells until they filled the entire cavity. The cavity contained materials that would be soon discharged into intercellular spaces and/or into the air. The cavity began to decrease the volume by contracting at initial secretion but degrade rapidly within short time. It has been suggested that the mode of secretion in V. negundo is probably the eccrine secretion, since no break or rupture of the cavity has been observed during examination. Contrastingly Type 3 exhibited deterioration of the head cell at early stage. Type 4 was about $110{\sim}190{\mu}m$ long, consisting of $2{\sim}3$ cells, and distributed more in the adaxial epidermis compared to the abaxial surface. However, $20{\sim}30{\mu}m$ long Type 5 was extremely dense in both epidermis. Among several trichome types, Type 1 and 2 probably play an important role in discharging unique aromatic scents in plants of V. negundo.

• Korean Journal of Plant Tissue Culture
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• v.26 no.4
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• pp.259-264
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• 1999

In order to study the role of ethylene on the formation of adventitious roots, trichomes and calli, the effects of 1-aminocyclopropane-l-carboxylic acid (ACC), ethephon, $CoCl_2$ and $AgNO_3$ were investigated in the leaf segments from ecotype Columbia of Arabidopsis thaliana. When the leaf segments were cultured on the media for forming adventitious roots (0.1 mg/L NAA), trichomes (2.0 mg/L NAA) and calli (10.0 mg/L NAA), and then each cultures was treated with 1-100 mg/L of ACC and ethephon, respectively. On the adventitious root-forming medium adventitious root formation was decreased, and trichomes were induced. And on the trichome-forming medium trichome formation was decreased, and calli were induced. In order hand each culture was treated with 1-100 mg/L of $CoCl_2$ and $AgNO_3$, respectively. On the adventitious root-forming medium adventitious roots was increased without trichome formation, and on the trichome-forming medium trichome formation was decreased, and adventitious roots were induced. However on the callus-forming medium treated with ACC, ethephon, $CoCl_2$ and $AgNO_3$, respectively, callus formation was inhibited and trichomes were induced in all cultures.

• Applied Microscopy
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• v.35 no.2
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• pp.97-104
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• 2005

Plant epidermis consists of relatively unspecialized cells and more specialized cells of various structure and function. Trichomes are specialized cells originated from the epidermis and much attention has been paid to the plants developing trichomes with peculiar structure and function. The present study has been undertaken to examine the trichome type noticed in the leaf epidermis of Althaea rosea using scanning electron microscopy. Four types, namely simple, short-and long-tufted, and glandular hairs, were detected in their epidermis. Their Distribution, frequency and structure varied by the development and epidermal surface. The most frequently distinguished type was the tufted ones growing in young leaves of the abaxial epidermis, while the simple hairs were rare throught the examination. The short-tufted hairs branched up to seven times having each branchlet about $160{\sim}210{\mu}m$ in length at maturity. The long-tufted hairs exhibited up to ten branchlets, where branchlets could reach up to $900{\sim}1,000{\mu}m$ long when fully expanded. Glandular trichome was the peltate type comprising $1{\sim}2$ secretory head cells, 2 stalk cells and a basal cell. The short peltate glandular hairs, usually not exceeding $40{\mu}m$, differentiated more along the areoles in the adaxial epidermis. The function of these trichomes in A. rosea has been still obscure, but it has been speculated that they probably play a role in protection; non-glandular ones possibly providing a defense against insects and secretory glandular type participating in chemical defense. Structural features of these trichomes at cellular level will be discussed in the following study of transmission electron microscopy.

• 한국전자현미경학회:학술대회논문집
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• 1997.05a
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• pp.39-39
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• 1997

• Proceedings of the Zoological Society Korea Conference
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• 2001.10a
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• pp.182.2-182
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• 2001

No Abstract, See Full Text

• 한국전자현미경학회:학술대회논문집
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• 2004.11a
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• pp.113-113
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• 2004

• 한국전자현미경학회:학술대회논문집
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• 2002.05a
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• pp.27-28
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• 2002