1. 본 연구는 GM콩이 비의도적으로 자연에 방출되었을 시 야생콩과의 교잡에 의해 발생 가능한 교잡콩을 모니터링하고 영양학적 측면에서 안전성을 평가하기 위하여 수행하였다. 이를 위해, 베타카로틴 강화 GM콩과 야생콩, 두 품종간 인위적으로 생산한 교잡콩, GM콩의 모본이자 일반 재배 품종인 광안콩 등 4품종을 국내 2개 지역에서 재배하고 콩 종자를 대상으로 주요 영양성분 38종을 분석하였다. 2. 재배 환경에 영향을 받지 않고, GM콩 및 야생콩과 비교해 교잡콩에서 유의적 차이를 보이는 성분은 조단백질, 조섬유, alanine, glycine, leucine, serine, tryptophan, oleic acid, linolenic acid, arachidonic acid 등 10종이었다. 하지만, 분석한 모든 시료의 성분은 국내외 자연 범위에 포함되는 수준이었다. 3. PCA분석 결과, 주요 영양성분 함량 변이는 GM콩은 모본과 유사하였고, 교잡콩은 GM콩 보다는 야생콩과 유사하였다. 즉, 분석한 4품종의 영양성분의 변이는 재배 환경보다는 유전적 요인에 의해 더 크게 영향을 받음을 알았다. 4. 본 연구의 결과는 GM콩과 야생콩간 교잡콩의 영양학적 안전성을 분석한 최초의 보고이며, 이는 향후 GM콩의 비의도적 자연 방출을 모니터링하는데 있어 유용한 기초 자료로써 활용 가치가 있을 것이다.
These experiments were to investigate the variations of rye on forage quality, productivity and β-carotene concentration affected by maturity in Pyeongchang region. Limited information are available about how forage quality and β-carotene content are affected by various factors. Samples were collected from rye harvested every 5 days, from April 25 to May 31 (April 25, April 30, May 4, May 9, May 15, May 21, May 25 and May 31). Dry matter (DM) content, plant height, DM yield and total digestible nutrient (TDN) yield increased continuously with the progressed maturity. However, crude protein (CP) content, in vitro dry matter digestibility (IVDMD) and relative feed value (RFV) decreased markedly with the delay of harvesting, while TDN content decreased from April 25 till May 15, then followed by a stable fluctuation. Conversely, acid detergent fiber (ADF) and neutral detergent fiber (NDF) value increased and then fluctuated slightly after blooming stage. For quality of plant parts, stem contained the lowest CP content and RFV value, and the highest ADF and NDF contents compared with other parts, while the grain showed the higher CP, IVDMD, RFV and lower fiber contents than others. With the plant matured, leaf proportion decreased while stem and grain proportion increased, and feed value of all the three parts decreased till blooming stage and followed by a stable phase. β-carotene concentration showed its highest on jointing stage, and then fell down sharply on the sequential stages. In conclusion, harvest around May 15 (blooming) is proper for forage rye if directly consumed by livestock as green chop in Pyeongchang under the consideration of both nutritive yield and forage quality.
본 연구는 조제유류 중「식품의 기준 및 성분규격」에 기준 규격이 설정되어 있지 않으나 제품에 함유되어 있는 베타카로틴에 대해 분석법을 마련하고자 수행하였다. 조제유류에 함유된 베타카로틴 함량 분석을 위해 HPLC를 이용한 분석법을 확립하고 시중에 유통 중인 제품을 대상으로 적용성을 검토하였다. 베타카로틴 표준품을 이용하여 HPLC를 이용한 기기분석조건을 확립하고 시료 중의 베타카로틴을 추출하여 분석하였다. 분석법 검증은 특이성, 직선성, 검출한계 및 정량한계, 정확성, 정밀성에 대해 수행되었다. 0.125~2 mg/L의 농도범위에서 R2=0.999 이상의 우수한 직선성을 확인할 수 있었으며, LOD와 LOQ는 각각 0.1, 0.2 mg/L였다. 표준물질 첨가법을 이용하여 정 확성을 검토하였으며, 81~120%의 회수율을 확인할 수 있었다. 정밀성을 검토한 결과 시료 채취량에 따른 반복성은 RSD값이 2.1~4.9%, 실험실간 교차검증을 통한 실험일자에 따른 재현성은 4.0 RSD(%)로 확인되었다. 본 연구에서 확립된 분석법을 적용하여 조제유류 13건, 성장기용 조제식 7건 등 국내 유통 중인 제품 20건에 대해 적용성 검토를 실시한 결과 전체 시료에서 분석이 용이하였으며, 모두 표시기준에 적합함을 확인하였다.
To determine the bioactive compound of domestic cherry tomato, the levels of lycopene, β-carotene, and phenolic compounds were analyzed in three domestic cherry tomato cultivars (Summerking, Qutiquti, and Minchal) using HPLC and LC-MS/MS. The levels of lycopene were 69.40 mg/100 g (Qutiquti), 69.07 mg/100 g (Minichal), and 38.52 mg/100 g (Summerking). The contents of β-carotene were 3.35 mg/100 g (Qutiquti), 2.30 mg/100 g (Summerking), and 2.25 mg/100 g (Minichal). Five phenolic compounds were identified exactly as 3-caffeoylquinic acid, 5-caffeoylquinic acid, quercetin-3-apiosylrutinoside, quercetin-3-rutinoside, and naringenin chalcone from three domestic cherry tomatoes. Five phenolic compounds were identified partially as two isomers of caffeic acid-hexose, caffeoylquinic acid isomer, di-caffeoylquinic acid, and tri-caffeoylquinic acid from three domestic cherry tomatoes. Naringenin chalcone was the most abundant phenolic compound, ranging from 78.2 mg/100 g for Qutiquti to 222.9 mg/100 g for Summerking. High levels of quercetin-3-rutinoside and 5-caffeoylquinic acid were found, ranging 24.3-50.8 mg/100 g and 31.8-47.6 mg/100 g, respectively. These results suggested that domestic cherry tomatoes can be used as bioactive food materials.
Vitamin A is essential for growth and differentiation of a number of cells and tissues, as result the precursor, a carotenoid β-carotene remains their essential source of vitamin A. However, the major problem this carotenoid face, is its susceptible to photodegradation and chemical oxidation, those properties make it difficult to use as an ingredient as functional food product and reduce its bioavailability. This study presents a novel approach to prepare a one-step inclusion complex using amylose microparticles as host molecule using amylosucrase from Deinococcus geothermalis (DGAS) and β-carotene nanoparticles, which were added into the DGAS enzyme reaction solution to entrap them during the synthesis of amylose chains. HRFE-SEM showing a spherical shape and average diameter of 4-8 μm; XRD and DSC showed an amorphous structure as well as less energy required to start the gelatinization process, due to the complexation of amylose chains with the β-carotene nano dispersion. Last but not least Raman spectroscopy was performed in order to confirmed the complex formation between β-carotene and amylose microparticles, showing the characteristic peaks of both compound. The stability test in this study showed the high stability of the complexed microparticles against environmental stresses such as, photodegradation and chemical oxidation. We expect this study contributes to the development of functional food materials to enhance the stability and bioavailability of active compounds.
β-carotene is present in carrots, pumpkins, and sweet potatoes. It suppresses many types of cancers by regulating cellular proliferation and apoptosis through a variety of mechanisms. However, the effects of β -carotene on oral cancer cells have not been clearly established. The main goal of this study was to investigate the effects of β-carotene on cell growth and apoptosis in oral cancer cells. Our results demonstrate that treatment with β-carotene induced inhibition of cell growth, and that the effect was dependent on β-carotene treatment time and concentration in KB cells. Furthermore, treatment with β-carotene induced nuclear condensation and fragmentation in KB cells. β-carotene promoted proteolytic cleavage of procaspase-3, -7, -8 and –9 with associated increases in the concentration of cleaved caspase-3, -7, -8 and –9. In addition, the level of cleaved PARP was increased by β-carotene treatment in KB cells. These results suggest that β-carotene can suppress cell growth and induce apoptosis in KB human oral cancer cells, and that it may have potential usefulness in anti-cancer drug discovery efforts.
무질서 매질에서 형광, 산란과 응집의 영향은 파장과 산란된 형광세기로 나타내는데, laser induced fluorescence(LIF) 분광학에 의한 분자특성으로 나타난다. 산란매질에서 광학적 효과는 광학적 파라미터들(μs, μa, μt)에 의해 표현되고 응집은 고-액상 분리공정과 Photodynamic therapy에서 중요 하게 활용되고 있다. 따라서 입자가 서로 접근될 때 콜로이드 입자들의 상호작용을 LIF와 응집효과로 분석하였다. 우리는 레이저 광원에서 검출기까지 거리의 함수에 의해 in vitro 시료의 산란과 형광 스펙 트라를 측정하였다. 산란계수 μs는 산란체의 입자가 증가함에 크게 나타났다. 그리하여 purple membrane vesicle과 β-carotene의 혼합물의 매질에서 광원에서 검출기에 의한 거리에 대한 측정된 값 (I, δ)이 거리가 가까워짐에 따라 크게 나타났다.
카로티노이드는 항산화 및 항암효과를 가지는 비타민 A의전구물질이다. 농촌진흥청 농업유전자원센터에서 보존하고 있는 호박자원 80자원의 과육에서 카로티노이드를 분석을 하였다. 유전자원은 한국, 멕시코, 인도의 원산지에 따라 호박 과육에서 카로티노이드를 분석하였다. 고성능 액체 크로마토그래피를 이용하여 총 9종의 카로티노이드 (크산토필류 3종과카로틴류 6종)를 분리하였다. 특히 카로티노이드 중 lutein과β-carotene 이 주로 분석이 되었다. 총 카로티노이드 함량 평균은 한국 육성종이 213.69 mg, 멕시코 재래종이 139.07mg, 인도 재래종이 69.13 mg, 그리고 한국 재래종 27.51 mg순으로 나타났다. 총 80 자원중 K188417(멕시코원산) 자원이카로티노이드 성분이 가장 많았다. 본 연구의 결과는 카로티노이드 고함유 호박 품종 개발 뿐 아니라 기능성 식품 개발의기초자료로 활용될 수 있을 것으로 사료된다.
This study aims to examine the effect of Genetically Modified β -Carotene Biofortified Rice rice developed by simultaneous expression technology in NAAS on biological immunity. Accordingly, this study added Genetically Modified β-Carotene Biofortified Rice 25, 50% and general rice 50% as control group into diet and provided rats with the prescribed feeds and then measured the contents of immunoglobulin and cytokine in blood. As a result, male and female IgM, IgE, male IgG1, female IgG2a and TNF-a, IL5 and IL12 showed no significant difference; male IgG2a tended to decrease dependently on the combined concentration of Genetically Modified β-Carotene Biofortified Rice; female IgG1 showed significance with control group, but its association with diet was not found. The higher the dietary mixing ratio, the more the male and female IFN-a and female IL-4 contents, regardless of rice variety, and it was found that female IL6 content decreased significantly, but its association with diet was not found. The risk of beta carotene-enriched rice into environment and human body has not been reported yet. The digestion of Genetically Modified β-Carotene Biofortified Rice can be seen as "safe" as this test result showed no big difference between general rice and Genetically Modified β-Carotene Biofortified Rice, and its usability is full of suggestions.
Nicotine, a major teratogen of cigarettes smoke induces embryonic abnormalities during the early stages of organogenesis. In this study, the protective effect of β-carotene against nicotine–induced embryos was evaluated by morphologic scoring, nile blue staining, lipid peroxidation, SOD activity assay and real-time PCR. The embryos exposed to nicotine (1 μM) revealed remarkable morphological anomalies compared to normal control group (p<0.05), but when β-carotene (1×10‒4 μM or 5×10‒4 μM) was added concurrently to the embryos exposed to nicotine, morphological parameters were significantly improved (p<0.05). Nicotine induced oxidative stress by increased lipid peroxidation, expression of proinflammatory cytokines (TNF-α and IL-1β), caspases-3 and decreased SOD activity. However, administration of β-carotene (1×10‒4 μM or 5×10‒4 μM) restored the SOD level and decreased oxidative damage in the embryos. These results indicate that β-carotene effectively counteracts the deleterious effects of nicotine on embryos and attenuates oxidative damage possibly through its antioxidant effects.
Seasoning oil(SO-1) was manufactured from soybean oil, with β-carotene, oleoresin paprika and 3 kinds of flavors. Color of it's SO-1 was red. Total content of trans fatty acid of SO-1 was low level 0.84%, compare to the butter's and margarine's 1.35%, 28.31%, respectively. Total volatile components of SO-1 was 201,313.11ppm, was higher than soybean oil's, butter's, margarine's and SO-2's(removed 3 kinds of flavors from SO-1), it's value of 63.54ppm, 481.24ppm, 168.95ppm and 205.73ppm, respectively. And smoke point(SP) of SO-1 was higher than others. SP of SO-1, after 6 months later at room temperature, was 240, in contrast with soybean oil's 228. This SO-1, added β-carotene and flavor components, had a masking effect of burnt flavor. From these results, SO-1 can be replaced of butter or margarine as a substituted oil.
The Robust Design method uses a mathematical tool called orthogonal arrays to study a large number of decision variables with a small number of experiments. It also uses a new measure of quality, called signal-to-noise (S/N) ratio, to predict the quality from the customer's perspective. Thus, the most economical product and process design from both manufacturing and customers' viewpoints can be accomplished at the smallest, affordable development cost. Many companies, big and small, high-tech and low-tech, have found the Robust Design method valuable in making high-quality products available to customers at a low competitive price while still maintaining an acceptable profit margin. A study to analyze and solve problems of a biochemical process experiment has presented in this paper. We have taken Taguchi's parameter design approach, specifically orthogonal array, and determined the optimal levels of the selected variables through analysis of the experimental results using S/N ratio.
Background : Carotenoids are pigments that are found in plants, fruits, bacteria, and fungi. β -carotene and canthaxanthin are orange pigments among thousands of carotenoids that possess potent antioxidant activity. The objective of this study was to determine β-carotene and cantaxanthin in 55 Kimchi cabbage germplasm using liquid chromatography mass spectrometry (LC-MS) method.
Method and Results : 55 Kimchi cabbage accessions were sown in plug trays in the end of August, 2016. All the tissue samples were freeze-dried for 1 week and ground into fine powder and stored at -20℃ until analysis. Crude carotenoids from freeze-dried materials (100 mg) were extracted using 1 ㎖ of 100% (v/v) hexane in 10 minutes by using sonication bath followed by centrifugation. The average β-carotene contents was 1.43 ㎎·㎏-1 and ranged from 0.76 (IT 120045) to 2.25 ㎎·㎏-1 (IT 100378). The average canthaxanthin content in the entire domain of sample was 0.59 ㎎·㎏-1 with a range between 0.36 (IT 32746) and 1.08 ㎎․㎏-1 (IT 100386). Canthaxanthin content was significantly positively correlated with β-carotene (r = 0.65**) and leaf length (r = 0.63**). However, canthaxanthin was negatively correlated with cotyledon color (r = -0.41**). Principal component analysis results of the first two components (PC1 and PC2) explained 44.53% of the point variability.
Conclusion : The resources with the highest β-carotene and canthaxanthin content are IT 100378, 100386, 100391, and 110828. This study could be useful to select a potential sources of health beneficial carotenoids (β-carotene and canthaxanthin) in Kimchi cabbage germplasm in nutraceutical formulations and for further applications as a breeding material and other research activities.
The β-carotene biofortified transgenic soybean was developed recently through Agrobacterium -mediated transformation using the recombinant PAC (Phytoene synthase-2A-Carotene desaturase) gene in Korean soybean (Glycine max L. cv. Kwangan). GM crops prior to use as food or release into the environment required risk assessments to environment and human health in Korea. Generally, transgenic plants containing a copy of T-DNA were used for stable expression of desirable trait gene in risk assessments. Also, information about integration site of T-DNA can be used to test the hypothesis that the inserted DNA does not trigger production of unintended transgenic proteins, or disrupt plant genes, which may cause the transgenic crop to be harmful. As these reasons, we selected four transgenic soybean lines expressing carotenoid biosynthesis genes with a copy of T-DNA by using Southern blot analysis, and analyzed the integration sites of their T-DNA by using flanking sequence analysis. The results showed that, T-DNA of three transgenic soybean lines (7-1-1-1, 9-1-2, 10-10-1) was inserted within intergenic region of the soybean chromosome, while T-DNA of a transgenic soybean line (10-19-1) located exon region of chromosome 13. This data of integration site and flanking sequences is useful for the biosafety assessment and for the identification of the β-carotene biofortified transgenic soybean.
The β-carotene biofortified transgenic rice was developed by transforming rice cv. Nakdongbyeo with phytoene synthase (Psy) and carotene desaturase (Crt I) genes isolated from Capsicum and Pantoea. The aim of this study was to perform molecular characterization of rice transformants of T5-T7 generation harboring Psy and Ctr I genes driven by endosperm specific globulin promoter for biosafety evaluation of β-carotene biofortified transgenic rice. The structure and sequence of T-DNA in the transformation vector and the insertion sites, flanking sequences and generational stability of inserted T-DNA in transgenic rice lines were analyzed. The transformation vector consisted of right border, MAR gene, carotenogenic genes unit, herbicide resistance selectable marker unit, MAR gene and left border in sequential order. T-DNA was introduced at the position of 30,363,938-30,363,973 bp of chromosome No. 2 by adaptor-ligation PCR. Stable integration of T-DNA and stable expression of bar gene was confirmed in T5 to T7 generations. It was also confirmed that the backbone DNA of transformation vector containing antibacterial gene was not present in the genome of β-carotene biofortified transgenic rice. HPLC analysis confirmed that carotenoids were consistently detected through T5-T7 generations.
The β-carotene biofortified transgenic soybean was developed recently through Agrobacterium-mediated transformation using the recombinant PAC (Phytoene synthase-2A-Carotene desaturase) gene in Korean soybean (Glycine max L. cv. Kwangan). GM crops prior to use as food or release into the environment required risk assessments to environment and human health in Korea. Generally, transgenic plants containing a copy of T-DNA were used for stable expression of desirable trait gene in risk assessments. Also, information about integration site of T-DNA can be used to test the hypothesis that the inserted DNA does not trigger production of unintended transgenic proteins, or disrupt plant genes, which may cause the transgenic crop to be harmful. As these reasons, we selected four transgenic soybean lines expressing carotenoid biosynthesis genes with a copy of T-DNA by using Southern blot analysis, and analyzed the integration sites of their T-DNA by using flanking sequence analysis. The results showed that, T-DNA of three transgenic soybean lines (7-1-1-1, 9-1-2, 10-10-1) was inserted within intergenic region of the soybean chromosome, while T-DNA of a transgenic soybean line (10-19-1) located exon region of chromosome 13. This data of integration site and flanking sequences is useful for the biosafety assessment and for the identification of the β-carotene biofortified transgenic soybean.