• Title/Summary/Keyword: Mesocarp

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Fruit wall anatomy of the genus Krigia (Asteraceae, Lactuceae) and their taxonomic implications (Krigia속의 과피의 해부학적 구조와 분류학적 의미)

  • Lee, Bok Won;Park, Ji Kuk;Pak, Jae-Hong
    • Korean Journal of Plant Taxonomy
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    • v.34 no.4
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    • pp.321-333
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    • 2004
  • We researched fruit wall anatomical characters about the seven taxa of Krigia and the nearest one relative, Nothocalais cuspidata by making use of the fruit wall anatomy, and inferred systematical similarity. Among these characters, all species of the genus Krigia has identical characters in the shape of fruit and the number of rib, but showed specific differences in the shape of costa, the numbers of libriform fiber cell layers and fiber-sclereid cell layers in mesocarp, and development degree in these characters. Krigia biflora, K. cespitosa, K. occidentalis and K. wrightii have well developed libriform fiber cell, but K. dandelion, K. montana and K. virginica have undeveloped libriform fiber cell, and mostly consist of fiber-sclereid cell layers. According to the fruit wall anatomical characters, K. biflora which belonged to sect. Krigia in the previous classification system is more similar to sect. Cymbia than sect. Krigia.

Assessment of anatomical characteristics of the medicinal plant African cherry (Prunus africana) for its accurate taxonomic identification

  • Komakech, Richard;Yang, Sungyu;Song, Jun Ho;Choi, Goya;Kim, Yong-Goo;Okello, Denis;Omujal, Francis;Kyeyune, Grace Nambatya;Matsabisa, Motlalepula Gilbert;Kang, Youngmin
    • Journal of Plant Biotechnology
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    • v.49 no.2
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    • pp.139-144
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    • 2022
  • The genus Prunus (family: Rosaceae) consists of over 400 plant species and exhibits vast biodiversity worldwide. Given the wide distribution of this genus, its taxonomic classification is important. Anatomical characteristics are conserved and stable and can therefore be used as an important tool for the taxonomic characterization of plants. Therefore, this study aimed to assess and document the anatomical characteristics of the leaf, stem, and seed of P. africana using micrographs and photographs for possible use in the identification, quality control, and phylogenetic analysis of the species. The anatomical sections of a young stem revealed a cortex consisting of isodiametric parenchyma cells, druse crystals, primary vascular bundles, and pith. The mature stem bark majorly consisted of the rhytidome, with the periderm densely arranged in multiple layers; a cluster of stone cells; and sclerenchyma. The leaf sections were hypostomatic, with stomata sizes ranging from 18.90-(22.34)-26.90 × 15.41-(18.40)-21.22 ㎛. The leaf sections showed the presence of characteristic druse crystals, vascular bundles, and mesophyll layers. The pericarp contained the epicarp, mesocarp, and endocarp, with their thickness being approximately 350-400, 300-350, and 30-50 ㎛, respectively. In addition, it contained a seed testa with a thickness of approximately 50-60 ㎛. The morphological and anatomical characteristics observed in P. africana leaves, stems, and seeds in this study could serve as useful data for the taxonomic identification of this species.

Schizandrin, Oil Compounds, and Their Extraction Yield in Fruits of Schizandra chinensis Baillon (오미자의 Schizandrin과 기름성분 및 추출수율 변화)

  • 김관수;박춘근;류수노;방진기;이봉호
    • KOREAN JOURNAL OF CROP SCIENCE
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    • v.45 no.3
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    • pp.158-162
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    • 2000
  • Histochemical distribution and varietal variation of schizandrin and oil compounds, and the changes of their extraction yield were investigated in fruits of collected Schizandra chinensis including Inje cultivar. In histochemical analysis on the distribution of schizandrin and oil in fruits of Inje cultivar, higher concentrations of them were found in the seed (1.01% and 27.6%, respectively) than in the epicarp and mesocarp of the whole fruit. Average contents of schizandrin in fruits and oil in seeds of collected lines were 0.84% and 27.9%, respectively. The mean composition of fatty acids in seeds oil was 3.6% of palmitic acid, 0.6% of stearic acid, 19.7% of oleic acid, 73.0% of linoleic acid, and 3.1% of linolenic acid, showing high composition(95.8%) of total unsaturated fatty acid. Oil extracted from seeds of Inje cultivar contained 4.29% of schizandrin, indicating that seed oil contained much schizandrin, a bioactive lipid-soluble compound. Compared with 80% methanol extraction in fruits and seeds, yields of schizandrin and oil were lower showing 23.8% and 17.3%, respectively in boiling water extraction of the fruits and seeds without grinding. The seeds soaked with water during four months contained 1.18% of schizandrin and 25.2% of oil, whose contents were similar to those of the seeds stored at room temperature. These results demonstrated that the seed in the whole fruit could be utilized as a source to extract its functional oil and bioactive lipid-soluble compounds like schizandrin, especially after using Schizandra fruits for the beverage manufacture.

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The nutlet morphology of the genus Glechoma L. (Lamiaceae) and its related taxa (긴병꽃풀속(Glechoma L. 꿀풀과) 및 근연분류군의 소견과 형태에 관한 연구)

  • Jang, Tae-Soo;Hong, Suk-Pyo
    • Korean Journal of Plant Taxonomy
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    • v.40 no.1
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    • pp.50-58
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    • 2010
  • The nutlet morphology and pericarp structure of 14 taxa (4 taxa of the genus Glechoma and related taxa) were studied by light and scanning electron microscopy, and a detailed description of nutlet morphological features for all examined taxa is provided. The shape of the nutlet is ovate to elliptic. Its size is 1.36-3.83 mm in length and 0.80-2.65 mm in width. The largest one was found in Marmoritis rotundifolia, while the smallest one was in Agastache nepetoides. Three different surface types were recognized in the studied taxa based on differences in cell outline and cell boundary relief (rectangular, pitted, and ridged negative reticulate-cell). Three types of trichome (uni-cellular non-glandular trichome, multi-cellular non-glandular trichome, and peltate glandular trichome) were distributed in the nutlets. The pericarp is formed in three layers (i.e., exocarp, mesocarp, and endocarp including sclenchyma tissue), and the pericarp in the studied species is $39.0-237.5{\mu}m$ thick. The morphological and anatomical features (the nutlet shape, surface type, and trichome distribution) in the genus Glechoma and related taxa are described and discussed.

Chemical Components Composition on Different Parts of Fruit in Schisandra chinensis Baillon (오미자 열매 부위별 이화학적 특성)

  • Lee, Ka Soon;Lee, Bo Hee;Seong, Bong Jae;Kim, Sun Ick;Han, Seung Ho;Kim, Gwan Hou;Park, Saet Byeol;Kim, Hyun Ho;Choi, Taek Yong
    • Journal of the Korean Society of Food Science and Nutrition
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    • v.45 no.6
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    • pp.851-858
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    • 2016
  • The effective components of Schisandra chinensis are lignans (schizandrins and gomisins), which have various physiological functionalities such as anti-cancer, anti-inflammatory, and antioxidant activities. This study was carried out to determine the different parts of fruits in Schisandra chinensis to elevate their usefulness. Schisandra chinensis was separated into skin (epicarp), pulp (mesocarp), and seeds, and raw Omija and hot-dried Omija (HDO) were used as control. The most abundant component was nitrogen free extract (6.88~56.70%) followed by crude lipids (1.65~19.04%). The main mineral was K (383.10~2,024.10 mg/100 g), except in seeds where P was the main mineral. The main lignan in all parts of fruit was schizandrin, and the highest content of schizandrin was 9.46 mg/g in dried seeds. Total lignan content was 25.97 mg/g and 14.97 mg/g in dried seeds and HDO, respectively. A total of 17 components of fatty acids in seeds and HDO were detected, of which linoleic acid (72.66~73.78%), oleic acid (14.78~17.39%), palmitic acid (2.88~3.54%), and capric acid (1.70~4.93%) were determined as the major components. Main lignans and fatty acids of Schisandra chinensis fruit contain mainly seeds. Therefore, it is more efficient to use seeds than pulp and extract of fruit itself to use the components of Omija.

Effect of 1-Methylcyclopropene (1-MCP) Treatment and MAP on Quality Changes of Peach 'Daehong' during Cold Storage (1-Methylcyclopropene(1-MCP)와 MAP 처리가 저온 저장 중 복숭아 '대홍'의 품질 변화에 미치는 영향)

  • Yoo Han Roh;Joo Hwan Lee;Yong Beom Kwon;In-Lee Choi;Haet-nim Jeong;Ho-Min Kang
    • Journal of Bio-Environment Control
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    • v.32 no.4
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    • pp.267-277
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    • 2023
  • This study is in order to the effect of 1-methlycyclopropene (1-MCP) treatment and film package as modified atmosphere packaging (MAP) on the changes in fruit quality factors of 'Daehong' peaches during cold storage. The concentrations of 1-MCP were treated at 1µL·L-1 and 2µL·L-1, and peaches in film package were stored for 28 days in cold storage at 5±1℃ and 85±5% RH. The fruits stored carton box were used as a control of MAP, and 1-MCP free fruits were used as the control of both packages. Rate of fresh weight loss during storage was not significantly different between groups with and without 1-MCP treatment, but was higher in the box package than in the MAP. The control group had a higher incidence of both gases with the 1-MCP treatment group showing statistically significantly low. Carbon dioxide in the package was lowered by about 12% compared to the non-treated group, and the ethylene concentration was maintained at 1µL·L-1, showing a significance low compared to other treated groups. As the storage period elapsed, the firmness of 1-MCP and MAP treated fruits remained significant at 5-9% compared to the control group. Regardless of the packaging method Hunter a* values of exocarp and mesocarp were significantly higher in fruit treated with 1-MCP 1µL·L-1 treatment than in the control group, and anthocyanin was significantly higher in the fruit during the storage period, especially high in MAP. In summary, fruits of MAP group with 1-MCP 1µL·L-1 had rate of lower respiration and ethylene production, and little changes in firmness, Hunter a* values of exo-carp and meso-carp, and anthocyanin, which is considered the most suitable method for preserving postharvest quality of the peach cultivar during the storage.