• 한국자원식물학회지
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• 제8권3호
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• pp.237-246
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• 1995

본 연구에서는 유자의 미성숙 배로부터 캘러스 유도와 재분화 및 발생단게별 미세구조적 특성에 관하여 연구하였다. 유자에서는 배양 5-6주 경에 담황색의 캘러스가 유도되었으며, 배양 6주경의 캘러스 세포에서는 인접하고 있는 작은 액포들이 융합하여 큰 액포를 형성하는 융합현상을 관찰하였다. 배양 12주 경에는 배발생 캘러스의 미분화 세포에서 특이하게 구형의 핵인을 가지고 있는 큰핵과 녹말로 가득차 있는 녹말체를 다수 관찰하였다. 배양 14-16주 경의 배발생 캘러스 세포에서는 활발하게 exocytosis가 일어나므로서 다수의 분배체들이 세포벽쪽에서 관찰되었으며 세포질로부터 작은 입자들이 세포 간극으로 빠져나가는 것을 볼수 있었다. 또한 배양 24주경의 배발생 캘러스에서는 발달된 커다란 구형의 엽록체들이 이중막으로 세포질과 경계되어 있었으며 기질중에 일정하게 전형적인 그라나가 분포되어 있었다. 배양 26주경의 어린 정상 식물체의 미성숙잎에서는 다수의 도관과 반세포들이 관찰되었다. 배양 30주경의 정상식물체의 미성숙잎에는 다수의 작은 반세포들과 사관 그리고 중심액포들이 나타났으며 또한 작은 제2차 액포들이 커다란 중심 액포 속으로 끼어들어가는 현상을 볼 수 있었으며 원형질막 근처에는 신장된 엽록체들이 분포되어 있었다.

• Applied Microscopy
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• 제39권4호
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• pp.333-340
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• 2009

다육질성 CAM 식물에서는 구조와 기능의 분화가 환경조건에 잘 적응된 합리적인 광합성을 수행하여 동일한 엽육세포에서 $CO_2$ 고정, 유기물 합성과 저장, 분해 및 활용하는 시간이 서로 다르게 나타난다. 이러한 유기산 대사는 CAM 식물의 가장 뚜렷한 대사적 특징으로 밤에 말산을 합성하여 액포에 저장하고 낮에 이용하므로 이들의 액포는 급격한 pH의 차이를 일주기성으로 조절해야 하는 매우 중요한 세포소기관이다. 본 연구에서는 식물체 내 생리적 건조가 지속되어 CAM 광합성을 수행하는 바위솔속 식물 3종의 다육질성 엽육조직 세포의 특성을 액포 구조분화에 초점을 두어 미세구조적으로 연구하였다. 바위솔속의 다육질성 엽육조직은 수분저장성 세포들로 구성되어 있으며, 액포융합 등의 액포화현상과 액포 내 다양한 2차 액포형성이 현저한 구조적 특징이었다. 이들 액포는 매우 역동적이어서 분열하여 다수의 소액포를 형성하거나 소액포들의 융합으로 큰 액포를 형성하였고, 일부는 전자밀도가 높은 저장성 액포로 발달하였다. 이러한 액포화는 세포의 크기를 경제적이고 에너지 효율적으로 증가시키는 방식으로 대부분의 다육질성 CAM 식물에서 발달하며, 낮과 밤에 일주기성으로 반복되는 세포 내 pH 농도의 급격한 변화를 대처할 수 있게 한다. 또한, 막 함입에 의한 다양한 크기의 수많은 2차 액포 형성은 단 기간 내에 액포막의 용적을 증가시켜 이러한 목적을 충족시켜 주는데 일주기적으로 사용되는 매우 중요한 세포 내 구획이 된다. 액포의 신장으로 세포질은 세포벽 주변부위로 밀려나 얇은 층으로 국한되었으나, 이들 세포질 내에서도 엽록체와 미토콘드리아는 액포와 밀접하게 연관되어 분포하고, 세포 간에는 원형질연락사가 잘 발달하였다. 이러한 미세구조들의 발달은 다육질성 엽육세포가 일주기성으로 급변하는 세포 내 유기산 대사과정에 적응하기 위해 액포에서의 신속하고 원활한 대사물질의 수송이 이루어져야 하기 때문일 것으로 추정된다.

• Plant Resources
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• 제3권3호
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• pp.163-172
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• 2000

We compared microstructural features of the ordered cell and disordered leaves in Citrus junos Sieb. by electron microscopy. In the cell of the ordered leaves, many chloroplasts and large vacuoles were particularly observed. Also a lot of vessel, companion cell and big nucleus were presented in vascular bundle regions. The mitochondria and the other organelles were interspersed among the chloroplasts in a thin, peripheral layer of cytoplasm. The chloroplast possessed typical grana and intergranal lamellae, numerous starch grains and a few small osmophilic globules. Besides, microbodies were closely associated with the mitochondria and the chloroplast. The process of the formation of the secondary cell wall from primary cell wall was observed the vessel elements, the tonoplast wall and the secondary cell wall. It was observed that the oil sac with the unique perfume distributed the adjacent cell wall. In the cell of disordered leaves, the all of the organelles were thrust toward the cell wall due to the fusion of vacuoles in the cells. It was observed that a lot of the very small particles spreaded in the cytoplasm. The loss of unique perfume of the leaves was resulted in the destruction of the oil sac. Also, there was not observed grana, lamellae, starch and osmophillic globules in the chloroplast. The small distributed organelles was not observed but the elongation of the cell wall was proceed no longer. Therefore, the plasma membrane diverged from the cell wall. All of organelles in the cell had poor function and deformation. A massive vacuole was fulfilled in single cell and the vacuole contains a lot of large and small particles. The organelles were presented on the side of the cell wall according to the enlargement of vacuole and they were observed to be breakdown.

• Applied Microscopy
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• 제16권2호
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• pp.49-60
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• 1986

Ultrastructures of the large and elongated cells (idioblasts) in the haustorium of a parasitic angiosperm, Cuscuta australis R. Brown growing on the host plant, Trifolium repens L. were investigated by the electron microscopy. The idioblasts were characterized by the presence of a large nucleus, small vacuoles, and dense cytoplasm including a number of various cell organelles such as ribosome, rough endoplasmic reticulum(r-ER), mitochondrion, dictyosome, proplastid, multilamellar structure(MLS), microfilament bundle(MFB), and cytosegresome. Therefore, it is suggested that the idioblasts are metabolical1y very active. Particularly, MLS, MFB, and cytosegresome observed in this study did not appear in the haustorial cells of the other parasitic angiosperms. MLS was transformed into vacuole and also incorporated with cell wall. MFB composed of microfilaments, about each 7.5 nm in diameter, was observed in nucleus and also cytoplasm. Some types of MFB were distinguished on the basis of arrangement of microfilaments. A part of cytoplasm sequestered by stacked cisternae of smooth ER(s-ER), cytosegresome, was altered into a vacuole which was formed by digestion of the sequestered cytoplasm and of cisternae of s-ER. Cell organelles such as MLS, MFB, and cytosegresome were discussed in relation to the metabolic control of the idioblasts.

• 한국어류학회지
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• 제19권3호
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• pp.201-209
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• 2007

광학현미경상에서 복섬, Takifugu niphobles의 피부 표면은 불규칙한 주름을 가지는데, 이들 주름은 등 쪽보다 배 쪽에서 훨씬 뚜렷했다. 피부계는 외부로부터 상피층과 진피층으로 구분되며, 상피층은 다층상피층으로 상피세포, 점액세포, 곤봉상세포, 과립세포 그리고 multivacuolar gland들로 구성되어 있었다. 상피세포는 표면세포, 중간세포, 기저세포로 구분되며, 표면상피의 자유면은 미세융기로 덮여 있었다. 상피층의 선세포는 단세포선과 다세포선으로 구분되었다. 점액분비선은 다세포선의 형태로 점액세포들은 중성 당단백질의 점액물질을 함유하고 있었다. Multivacuolar gland들은 장경 약 $20{\mu}m$의 vacuole cell들로 구성되어 있었다. Vacuole cell들은 커다란 중심공포를 가지며, 잘 발달된 desmosome으로 연결되어 있었다. 점액분비선과 multivacuolar gland는 등 쪽에 비해 배 쪽에서 훨씬 발달되어 있었다. 진피층의 두께는 배 쪽 피부계의 경우에는 상피세포층의 3~5배였다. 진피층은 치밀결합조직으로 교원섬유, 섬유세포, 가시의 기저부, 색소세포 및 다수의 신경세포 분포가 확인되었다.

• 한국어류학회지
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• 제17권4호
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• pp.248-254
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• 2005

Integumentary structure of the amberjack, Seriola dumerili, was examined by light and transmission electron microscopy. Integument of the amberjack consists of epidermal and dermal layers. The epidermal thickness is about $28.32{\mu}m$. The epidermal layer could be classified into superficial, intermediate, and basal layers by morphology and position of the supporting cells. Secretory cells of the epidermal layer were classified into mucous cells and club cells in the amberjack. Mucous cells contained acidic mucous and were alcian-blue positive with AB-PAS (pH 2.5) reaction. The club cells contained well-developed rough endoplasmic reticula and large central vacuole. Also, filament-rich cells were identified in the epidermal layer. The dermal layer consists mainly of collagenous fiber, and it contains fibrocytes and pigment cells. The cytoplasm of fibrocyte had a well-developed rough endoplasmic reticulum. The pigment cells contained electron-dense melanin granules.

• 한국어류학회지
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• 제17권2호
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• pp.98-104
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• 2005

Integumentary structures of the chub mackerel (Scomber japonicus) were examined by light and transmission electron microscopy. The integument of the fish was composed of epidermal and dermal layers. The epidermal thickness is about $20{\mu}m$ in TL 35~40 cm fish. The epidermal layer could be classified into superficial, intermediate, and basal layers by morphology and position of the supporting cells. The epidermal layer also possessed mucous cells, club cells and chloride cells. The area of secretory cells, including mucous and club cells, is about 23% of the epidermal layer. The mucous materials were identified as sulfated glycoprotein, neutral and acid in nature. Club cells had a large central vacuole and rough endoplasmic reticula in the cytoplasm. Chloride cells had numerous tubular mitochondria in the cytoplasm. The dermal layer consists mainly of collagenous fiber, and it contains fibrocytes, pigment cells and cycloid scales.

• Journal of Ginseng Research
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• 제16권1호
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• pp.44-52
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• 1992

This study investigated ginsenosides and tissue characteristics of roots injured by physiological disorder, rusty and rough skin. After separation to cortex and stele parts of healthy, rusty (red) and rough skin roots, respectively, the contents of saponin and ginsenosides were analyzed. And also, the histological and cytological characteristics of cortex and stele parts were investigated. Crude saponin contents were little different among healthy, rusty (red) and rough skin root and ginsenesides as - Rgl, - Re and - Rbl were largely detected both in stele and cortex part. The ratio of PT/PD showed about 1:1 in three kinds of root. In histological study, destoryed cells in epidermis of rusty(red) root, and those in epidermis and exodermis of rough skin root were observed. The cells in cortex of rusty (red) and rough skin root have generally nucleus with unfixed shape, unequal cell wall, large number of vacuole and mitochondris, and unidentified dark substances compared to healthy root. But in cell of stele tissue, most of organellE seems to be normal except a small number of cells in rough skin root.

• Journal of Plant Biology
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• 제34권1호
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• pp.1-8
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• 1991

A sequential sub-cellular study of the epicarp of Nerium indicum has been performed. Outer epidermis of the ovary wall is covered externally with a thin cuticle. Cytoplasm possesses most of the cell organelles in the ovary stage itself. Outermost zone of the pericarp is the epicarp, developing from the outer epidermis. In the developing fruit, cell organelles are found with its maximum intensity. In mature fruit, the epicarp becomes multilayered due to additional development of few collenchymatous cells close to the outermost layer. Epicarpic cell possesses large central vacuole, around which a thin layer of cytoplasm is present. Number of cell organelles are considerably reduced in the mature fruit. In the ovary stage starch grains are electron transparent, while in the mature fruit it is fruit it is electron transluscent.

• Applied Microscopy
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• 제24권4호
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• pp.86-97
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• 1994

Protein bodies in the endosperm cells of mature red ginseng (Panax ginseng C.A. Meyer) were distributed evenly in the cytoplasm and their size varied from 1 to $8{\mu}m$. Three types of protein bodies were detected and they are spherical or egg-shaped ones containing homogeneous matrix only, spherical ones containing globoids, and irregular shaped ones. Protein bodies degraded in two patterns, one is to start the degration of the body from the surface toward the center, while the other is that the body was broken evenly and then degraded gradually. After degradation, only the limiting membrane remained, that causes the body to be empty. The limiting membranes fused with each other to form a large vacuole. Vicilin and legumin decreased in the endosperm cells as the protein bodies degraded gradually whereas they increased in the umbiliform layers.