Nguyen Thi Hang Phuong, T. Uchino, F. Tanaka, F. Tanaka
{"title":"Effect of 1-methylcyclopropene (1-MCP) and Temperature on the Quality of Broccoli during Storage","authors":"Nguyen Thi Hang Phuong, T. Uchino, F. Tanaka, F. Tanaka","doi":"10.2525/ecb.60.43","DOIUrl":"https://doi.org/10.2525/ecb.60.43","url":null,"abstract":"","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2022-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"47172754","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
The primary morphogenic pathway leading to the whole plant regeneration involves shoot organogenesis followed by root organogenesis in vitro (Malepszy, 2009). Apart from plant growth regulators, many treatments have been applied to improve the efficiency of regeneration of explant. One of them is incubation of cultures for a certain time under stress condition (low and high temperature, drought, salinity, metal). These types of stress have been found to have a positive effect on regeneration of plants (Puijalon et al., 2008). Aluminum (Al) is the 3rd most abundant element in the Earth’s crust (after oxygen and silicon), accounting for roughly 7% by mass. In soil, Al ions can be toxic to plants, but in combination with other minerals, it increases plant growth by enhancing phosphorus availability and activating the genes associated with abiotic stress (Noor et al., 2019). The effect of Al on plant growth, both toxic and beneficial, depends on the concentration and varies with species, physiological age, and growth conditions (Bojórquez-Quintal et al., 2017). Aluminum chloride (AlCl3) can produce metallic stress condition when added to culture media (Gallego et al., 2002). It enhanced shoot regeneration in date palm (Al-Mayahi, 2019), and increased micro-tuber and tuberous root production in Gloriosa superba L. (Subiramani et al., 2019). However, whether it can be used in orchid in vitro culture has not been reported yet. Cymbidium species are highly valued in the flower market due to its attractive foliage, flower color and pleasant aroma. So, a high quality plantlet is always on demand. Based on morphological and ecological characters, the genus Cymbidium can be differentiated into two types, protocorm-forming and rhizome-forming (Shimasaki and Uemoto, 1987). The protocorm and protocormlike body (PLB) forming type of Cymbidium are epiphytic, mostly common in tropical or subtropical regions and the rhizome-forming type includes terrestrial or saprophyte, which is widely distributed in oriental regions. The organogenetic pathways of PLB-forming and rhizome-forming types of Cymbidium are different (Ogura-Tsujita et al., 2007). The PLBs of PLB-forming Cymbidium are developed from apical meristem culture in vitro and developed shoots and roots within short period. In case of rhizomeforming types, rhizomes are developed directly from apical meristem culture in vitro and started forming more branches. However, shoot formation of a rhizome-forming type of Cymbidium is difficult compare with of PLB-forming type under an in vitro condition because rhizome has long dormancy period than PLBs (Shimasaki and Uemoto, 1987). In the present study we investigated the metallic stress effects of AlCl3 on in vitro cultures of two types of Cymbidium to identify its optimum concentration for regeneration of PLBs or rhizomes from inoculated PLB or rhizome, respectively, and formation of shoots and roots.
{"title":"Effect of Aluminum Chloride on the Organogenesis of Two Types of Cymbidium In Vitro","authors":"A. Ona, K. Shimasaki, Md Asif Emteas","doi":"10.2525/ecb.60.85","DOIUrl":"https://doi.org/10.2525/ecb.60.85","url":null,"abstract":"The primary morphogenic pathway leading to the whole plant regeneration involves shoot organogenesis followed by root organogenesis in vitro (Malepszy, 2009). Apart from plant growth regulators, many treatments have been applied to improve the efficiency of regeneration of explant. One of them is incubation of cultures for a certain time under stress condition (low and high temperature, drought, salinity, metal). These types of stress have been found to have a positive effect on regeneration of plants (Puijalon et al., 2008). Aluminum (Al) is the 3rd most abundant element in the Earth’s crust (after oxygen and silicon), accounting for roughly 7% by mass. In soil, Al ions can be toxic to plants, but in combination with other minerals, it increases plant growth by enhancing phosphorus availability and activating the genes associated with abiotic stress (Noor et al., 2019). The effect of Al on plant growth, both toxic and beneficial, depends on the concentration and varies with species, physiological age, and growth conditions (Bojórquez-Quintal et al., 2017). Aluminum chloride (AlCl3) can produce metallic stress condition when added to culture media (Gallego et al., 2002). It enhanced shoot regeneration in date palm (Al-Mayahi, 2019), and increased micro-tuber and tuberous root production in Gloriosa superba L. (Subiramani et al., 2019). However, whether it can be used in orchid in vitro culture has not been reported yet. Cymbidium species are highly valued in the flower market due to its attractive foliage, flower color and pleasant aroma. So, a high quality plantlet is always on demand. Based on morphological and ecological characters, the genus Cymbidium can be differentiated into two types, protocorm-forming and rhizome-forming (Shimasaki and Uemoto, 1987). The protocorm and protocormlike body (PLB) forming type of Cymbidium are epiphytic, mostly common in tropical or subtropical regions and the rhizome-forming type includes terrestrial or saprophyte, which is widely distributed in oriental regions. The organogenetic pathways of PLB-forming and rhizome-forming types of Cymbidium are different (Ogura-Tsujita et al., 2007). The PLBs of PLB-forming Cymbidium are developed from apical meristem culture in vitro and developed shoots and roots within short period. In case of rhizomeforming types, rhizomes are developed directly from apical meristem culture in vitro and started forming more branches. However, shoot formation of a rhizome-forming type of Cymbidium is difficult compare with of PLB-forming type under an in vitro condition because rhizome has long dormancy period than PLBs (Shimasaki and Uemoto, 1987). In the present study we investigated the metallic stress effects of AlCl3 on in vitro cultures of two types of Cymbidium to identify its optimum concentration for regeneration of PLBs or rhizomes from inoculated PLB or rhizome, respectively, and formation of shoots and roots.","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2022-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"49084562","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
M. Kitano, K. Nomura, T. Yamazaki, T. Iwao, M. Saitou, M. Mori, D. Yasutake, T. Kaneko, H. Ukeda, Satoshi Ishizuka, T. Fujiwara, Toshihiro Okabayashi
{"title":"Internet of Plants (IoP) Empowers Bottom-up Innovations in Greenhouse Horticulture","authors":"M. Kitano, K. Nomura, T. Yamazaki, T. Iwao, M. Saitou, M. Mori, D. Yasutake, T. Kaneko, H. Ukeda, Satoshi Ishizuka, T. Fujiwara, Toshihiro Okabayashi","doi":"10.2525/ecb.60.3","DOIUrl":"https://doi.org/10.2525/ecb.60.3","url":null,"abstract":"","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2022-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"44542252","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
D. Wambrauw, T. Kashiwatani, Maiko Matsuhashi, Satomi Yasuhara, Satoshi Oku, H. Shimura, K. Honda, T. Maeda, Takayuki Yamaguchi
Asparagus (Asparagus officinalis L.) is one of the most widely produced vegetables in the world. Green and white spears originate from the same cultivar but are produced using different cultivation methods in Japan. White spears are shielded from sunlight, i.e., spears that grow in the absence of light, and green and white spears contain different phytochemicals due to these differences (presence vs. absence of light). Green spears contain rutin, while white spears do not have rutin but are rich in saponin (protodioscin) (Maeda et al., 2005, 2008, 2012). Rutin is one of the most significant flavonoids that has been reported to have biological activities, such as hypertension prevention, anti-inflammatory, anti-tumor, anti-bacterial/ viral, and potent radical-scavenging properties. Rutin also has protective effects against capillary fragility and arteriosclerotic vascular changes (Griffith Jr. et al., 1944; Hellerstein et al., 1951; Middleton et al., 2000; Calabro et al., 2005; Guo et al., 2007). Consumer interest in functional foods, such as flavonoids, is increasing; and this interest has been stimulated by the potential health benefits that have arisen from the antioxidant activities of these compounds (Maeda et al., 2006). The main genes involved in rutin biosynthetic pathway are chalcone synthase (CHS), chalcone isomerase (CHI), favanone-3-hydroxylase (F3H), favonoid-3¢-hydroxylase (F3¢H), and flavonol synthase (FLS), glucosyltransferase (GT) and rhamnosyltransferase (RT) (Fig. 1). Studies have revealed that light is one of the most important environmental signals regulating flavonoid biosynthesis (Fuglevand et al., 1996; Jenkins, 1997, 2001; Wade et al., 2001; Maeda et al., 2010; Kopsell and Sams, 2013; Carvalho and Folta, 2014). Supplemental lighting is introduced when asparagus is grown using the “Fusekomi” forcing culture technique, which is a unique cropping technique developed in Japan. With this technique, it was found that the amount of rutin increased as the number of lamps and the duration of light exposure increased, while spear color improved (Wambrauw et al., 2016). Nonetheless, the mechanisms behind this rutin enhancement have not been fully clarified. In addition, only a few studies have addressed the molecular basis of flavonoid metabolism regulation in asparagus (Yi et al., 2019), the effect of light on the accumulation of flavonoid-related genes and the role of light-regulated genes in enhancing rutin production. Therefore, we investigated the effects of light on rutin-related expressions of biosynthetic genes (CHS, CHI, F3H, F3¢H, FLS) and the amount of rutin in green (light-exposed) and white (light-shielded) spears.
芦笋(Asparagus officinalis L.)是世界上最广泛生产的蔬菜之一。绿色和白色的矛源自同一品种,但在日本采用不同的栽培方法生产。白色的矛不受阳光的照射,也就是说,矛在没有光的情况下生长,由于这些差异(有光和没有光),绿色和白色的矛含有不同的植物化学物质。绿矛含有芦丁,白矛不含芦丁,但富含皂苷(原薯蓣皂苷)(Maeda et al., 2005, 2008, 2012)。芦丁是一类重要的黄酮类化合物,具有预防高血压、抗炎、抗肿瘤、抗细菌/病毒和清除自由基等生物活性。芦丁还具有防止毛细血管脆性和动脉硬化性血管改变的保护作用(Griffith Jr. et al., 1944;Hellerstein et al., 1951;Middleton et al., 2000;Calabro等人,2005;郭等人,2007)。消费者对功能性食品(如类黄酮)的兴趣正在增加;这些化合物的抗氧化活性所产生的潜在健康益处激发了这种兴趣(Maeda等人,2006年)。芦丁生物合成途径中涉及的主要基因有查尔酮合成酶(CHS)、查尔酮异构酶(CHI)、蚕豆酮-3-羟化酶(F3H)、黄酮类3-ⅱ-羟化酶(F3ⅱH)以及黄酮醇合成酶(FLS)、葡萄糖基转移酶(GT)和鼠李糖基转移酶(RT)(图1)。研究表明,光是调节类黄酮生物合成最重要的环境信号之一(Fuglevand et al., 1996;Jenkins, 1997,2001;Wade et al., 2001;Maeda et al., 2010;Kopsell and Sams, 2013;Carvalho and Folta, 2014)。当使用“Fusekomi”强制栽培技术种植芦笋时,引入了补充照明,这是日本开发的一种独特的种植技术。通过这种技术,我们发现芦丁的含量随着灯的数量和光照时间的增加而增加,而矛的颜色也有所改善(Wambrauw et al., 2016)。尽管如此,这种芦丁增强背后的机制尚未完全阐明。此外,仅有少数研究涉及芦笋类黄酮代谢调控的分子基础(Yi et al., 2019)、光照对类黄酮相关基因积累的影响以及光照调控基因在促进芦丁生成中的作用。因此,我们研究了光照对绿(光暴露)和白(光屏蔽)幼苗中与芦丁相关的生物合成基因(CHS、CHI、F3H、F3ⅱH、FLS)表达和芦丁含量的影响。
{"title":"Expression Analysis of Flavonoid-related Genes in Green and White Asparagus Spears","authors":"D. Wambrauw, T. Kashiwatani, Maiko Matsuhashi, Satomi Yasuhara, Satoshi Oku, H. Shimura, K. Honda, T. Maeda, Takayuki Yamaguchi","doi":"10.2525/ecb.59.191","DOIUrl":"https://doi.org/10.2525/ecb.59.191","url":null,"abstract":"Asparagus (Asparagus officinalis L.) is one of the most widely produced vegetables in the world. Green and white spears originate from the same cultivar but are produced using different cultivation methods in Japan. White spears are shielded from sunlight, i.e., spears that grow in the absence of light, and green and white spears contain different phytochemicals due to these differences (presence vs. absence of light). Green spears contain rutin, while white spears do not have rutin but are rich in saponin (protodioscin) (Maeda et al., 2005, 2008, 2012). Rutin is one of the most significant flavonoids that has been reported to have biological activities, such as hypertension prevention, anti-inflammatory, anti-tumor, anti-bacterial/ viral, and potent radical-scavenging properties. Rutin also has protective effects against capillary fragility and arteriosclerotic vascular changes (Griffith Jr. et al., 1944; Hellerstein et al., 1951; Middleton et al., 2000; Calabro et al., 2005; Guo et al., 2007). Consumer interest in functional foods, such as flavonoids, is increasing; and this interest has been stimulated by the potential health benefits that have arisen from the antioxidant activities of these compounds (Maeda et al., 2006). The main genes involved in rutin biosynthetic pathway are chalcone synthase (CHS), chalcone isomerase (CHI), favanone-3-hydroxylase (F3H), favonoid-3¢-hydroxylase (F3¢H), and flavonol synthase (FLS), glucosyltransferase (GT) and rhamnosyltransferase (RT) (Fig. 1). Studies have revealed that light is one of the most important environmental signals regulating flavonoid biosynthesis (Fuglevand et al., 1996; Jenkins, 1997, 2001; Wade et al., 2001; Maeda et al., 2010; Kopsell and Sams, 2013; Carvalho and Folta, 2014). Supplemental lighting is introduced when asparagus is grown using the “Fusekomi” forcing culture technique, which is a unique cropping technique developed in Japan. With this technique, it was found that the amount of rutin increased as the number of lamps and the duration of light exposure increased, while spear color improved (Wambrauw et al., 2016). Nonetheless, the mechanisms behind this rutin enhancement have not been fully clarified. In addition, only a few studies have addressed the molecular basis of flavonoid metabolism regulation in asparagus (Yi et al., 2019), the effect of light on the accumulation of flavonoid-related genes and the role of light-regulated genes in enhancing rutin production. Therefore, we investigated the effects of light on rutin-related expressions of biosynthetic genes (CHS, CHI, F3H, F3¢H, FLS) and the amount of rutin in green (light-exposed) and white (light-shielded) spears.","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2021-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"47533244","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
In the closed-type plant factories, artificial light sources, such as fluorescent lamps and light-emitting diodes (LEDs), are widely used as alternatives to sunlight. They, along with setting optimum environmental conditions (light, temperature, humidity, CO2, concentration of nutrient solution, and so on), can improve the productivity per unit area, and consequently increase the profit from small cultivation areas (Goto, 2012). However, only a few enterprises make a profit, due to the high initial cost for construction of closed-type plant factory units and the running costs of electric power such as lighting and air conditioning (Benke and Tomkins, 2017; Kozai, 2013). To reduce the running cost, LEDs are used as artificial light sources for plant growth, because of their lower power consumption and longer life span compared to fluorescent lamps. The morphogenesis of plants depends on the light spectra, and the illumination of LEDs is composed of a narrow range of wavelengths on the electromagnetic spectrum. Chlorophylls in plants mainly absorb red and blue lights and perform photosynthesis (Mohr and Schopfer, 1998); thus, several previous studies investigated the ability to increase yields by enhancing the efficiency of using these two colors. Shimokawa et al. (2014, 2020) investigated the growth of three cultivars of leaf lettuce, i.e., Summer Surge, Black Rose, Green Span (Lactuca sativa L. var. crispa) using Shigyo’s method, which involves alternating irradiation with red (LED; 660 nm, 100 mmol m 2 s ) and blue (LED; 450 nm, 60 mmol m 2 s ) lights. They found that this method enhanced the growth of two cultivars, i.e., Summer Surge and Black Rose, by increasing SFW compared to those under fluorescent light or simultaneous irradiation with red and blue lights. Using romaine lettuce (Lactuca sativa L. cv. Cos Lettuce), Jishi et al. (2016) examined the irradiation patterns of various combinations of red (LED, 90 mmol m 2 s ) and blue (LED, 90 mmol m 2 s ) lights, such as simultaneous red―blue irradiation as well as irradiation with shifted red-light period, based on the study of Hanyu and Shoji (2002), in which they found that using blue light irradiation just before entering the light period promoted the growth of spinach. When a photoperiod was set using a cycle of blue monochromatic light; red monochromatic light; and dark period, the total leaf area and SFW were maximized. Kuno et al. (2017) investigated the cultivation of leaf lettuce (Lactuca sativa L. var. crispa ‘Greenwave’) under simultaneous irradiation, alternating irradiation and shifted irradiation of red (LED, 120 mmol m 2 s ) or blue (LED, 120 mmol m 2 s ) light periods. The SFW obtained using alternating irradiation was significantly larger compared to that obtained using simultaneous irradiation. The SFW obtained using red monochromatic light was also large. Takasu et al. (2019) examined the optimum conditions for using alternating irradiations (ALTs) to cultivate Lactuca sativ
在封闭式植物工厂中,荧光灯和发光二极管(led)等人工光源被广泛用作日光的替代品。它们与设置最佳环境条件(光线、温度、湿度、二氧化碳、营养液浓度等)一起,可以提高单位面积的生产率,从而增加小种植面积的利润(Goto, 2012)。然而,只有少数企业盈利,这是由于封闭式工厂单元建设的初始成本高,以及照明和空调等电力的运行成本(Benke和Tomkins, 2017;Kozai, 2013)。为了降低运行成本,led被用作植物生长的人工光源,因为与荧光灯相比,它们的功耗更低,寿命更长。植物的形态发生依赖于光的光谱,而led的照明是由电磁波谱上的一个狭窄的波长范围组成的。植物中的叶绿素主要吸收红光和蓝光并进行光合作用(Mohr and Schopfer, 1998);因此,之前的几项研究调查了通过提高这两种颜色的使用效率来提高产量的能力。Shimokawa等人(2014,2020)采用Shigyo的方法对夏涌、黑玫瑰、绿跨(Lactuca sativa L. var. crispa)三种叶莴苣品种的生长进行了研究,该方法涉及红色(LED;660 nm, 100 mmol m 2 s)和蓝色(LED;450nm, 60mmol m 2 s)光。他们发现,与荧光灯或红蓝光同时照射相比,这种方法通过增加SFW来促进两个品种的生长,即夏浪和黑玫瑰。使用长叶莴苣(Lactuca sativa L. cv。Cos Lettuce), Jishi等人(2016)基于Hanyu和Shoji(2002)的研究,研究了红色(LED, 90 mmol m 2 s)和蓝色(LED, 90 mmol m 2 s)光的各种组合的照射模式,如红蓝同时照射和红光期转移照射,他们发现在进入光期之前使用蓝光照射促进了菠菜的生长。当使用一个蓝色单色光周期设置一个光周期时;红色单色光;暗期,总叶面积和SFW最大。Kuno等人(2017)研究了红光(LED, 120 mmol m 2 s)或蓝光(LED, 120 mmol m 2 s)同时照射、交替照射和位移照射下叶莴苣(Lactuca sativa L. var. crispa ' Greenwave ')的培养。交替照射获得的SFW明显大于同时照射获得的SFW。用红色单色光获得的SFW也很大。Takasu等人(2019)研究了在9种不同比例的红光(LED, 100 mmol m 2 s)和蓝光下,利用交替照射(ALTs)培养Lactuca sativa L. var. crispa ' Greenwave '的最佳条件
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Artificial light is a primary source of energy which influence the morphogenesis and growth of plant cell, tissue and organ in tissue culture techniques (Reuveni and Evenor, 2007). For commercial micropropagation, using LEDs as a radiation source is increasing. To find out a optimum lighting condition is very importat for mass propagation of orchids. The effects of LED lights were studied in various orchid species (Anuchai and Hsieh, 2017; Kaewjampa and Shimasaki, 2012; Mengxi et al., 2011; Ramírez-Mosqueda et al., 2017). But most of the studies focus on red and blue LEDs. Hence, this study was taken to investigate effect of monochromic green LED, and alternating lighting condition of red, blue and green LEDs on PLB proliferation, fresh weight, shoot and root formation by protocorm-like bodies of a Cymbidium cultivar.
在组织培养技术中,人造光是影响植物细胞、组织和器官形态发生和生长的主要能量来源(Reuveni and Evenor, 2007)。对于商业微传播,使用led作为辐射源正在增加。寻找适宜的光照条件对兰科植物的大量繁殖具有重要意义。研究了LED灯对不同兰花品种的影响(Anuchai and Hsieh, 2017;Kaewjampa and Shimasaki, 2012;梦曦等,2011;Ramírez-Mosqueda等人,2017)。但大多数研究都集中在红色和蓝色led上。因此,本研究研究了单色绿色LED和红、蓝、绿色LED交替光照条件对大花蕙兰原球茎样体PLB增殖、鲜重、茎部和根形成的影响。
{"title":"Effects of Different LED Lights on the Organogenesis of a Cymbidium Cultivar","authors":"A. Ona, K. Shimasaki, Md Asif Emteas, A. Uddin","doi":"10.2525/ecb.59.197","DOIUrl":"https://doi.org/10.2525/ecb.59.197","url":null,"abstract":"Artificial light is a primary source of energy which influence the morphogenesis and growth of plant cell, tissue and organ in tissue culture techniques (Reuveni and Evenor, 2007). For commercial micropropagation, using LEDs as a radiation source is increasing. To find out a optimum lighting condition is very importat for mass propagation of orchids. The effects of LED lights were studied in various orchid species (Anuchai and Hsieh, 2017; Kaewjampa and Shimasaki, 2012; Mengxi et al., 2011; Ramírez-Mosqueda et al., 2017). But most of the studies focus on red and blue LEDs. Hence, this study was taken to investigate effect of monochromic green LED, and alternating lighting condition of red, blue and green LEDs on PLB proliferation, fresh weight, shoot and root formation by protocorm-like bodies of a Cymbidium cultivar.","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2021-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"43225392","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
L. Le, H. T. Dinh, H. Takaragawa, Kenta Watanabe, Y. Kawamitsu
Photosynthesis is a crucial process for the existence, development, and productivity of crops, which directly impacts the world food security (Amthor, 2000; Simkin, 2019). Hence, the photosynthesis of plants has been meticulously studied. One of the concerned research directions is to build plant growth models based on the photosynthesis process (Fourcaud et al., 2008; Wu et al., 2019; Amitrano et al., 2020). Therefore, to build accurate models, the photosynthetic measurement methods should be suitable and engender the most accurate results possible. Currently, two popular photosynthesis measurement methods are available which are, namely, the single-leaf measurement method and the whole-plant measurement method (for short, single-leaf, and whole-plant method, respectively). The application of the whole-plant method will overcome deviations in photosynthesis of plants introduced by differences in canopy structure, leaf ages, mutual shading, and leaf orientation (Lanoue et al., 2017; Nomura et al., 2020). The single-leaf method may not overcome those deviations without applying a proper practice. On the contrary, the advantage of the single-leaf method is its convenience and ease of measurement, and it can be flexibly moved in the measurement site. Therefore, in this study, we compare measurements of the whole-plant and singleleaf method on strawberry plants (Fragaria ananassa Duch.) grown under plant factory conditions to provide an overview of measurement methods for this plant species. The strawberry is a small herbaceous species with high economic values and convenient for the cultivation and measurement of photosynthesis.
{"title":"Whole-plant and Single-leaf Photosynthesis of Strawberry under Various Environmental Conditions","authors":"L. Le, H. T. Dinh, H. Takaragawa, Kenta Watanabe, Y. Kawamitsu","doi":"10.2525/ecb.59.173","DOIUrl":"https://doi.org/10.2525/ecb.59.173","url":null,"abstract":"Photosynthesis is a crucial process for the existence, development, and productivity of crops, which directly impacts the world food security (Amthor, 2000; Simkin, 2019). Hence, the photosynthesis of plants has been meticulously studied. One of the concerned research directions is to build plant growth models based on the photosynthesis process (Fourcaud et al., 2008; Wu et al., 2019; Amitrano et al., 2020). Therefore, to build accurate models, the photosynthetic measurement methods should be suitable and engender the most accurate results possible. Currently, two popular photosynthesis measurement methods are available which are, namely, the single-leaf measurement method and the whole-plant measurement method (for short, single-leaf, and whole-plant method, respectively). The application of the whole-plant method will overcome deviations in photosynthesis of plants introduced by differences in canopy structure, leaf ages, mutual shading, and leaf orientation (Lanoue et al., 2017; Nomura et al., 2020). The single-leaf method may not overcome those deviations without applying a proper practice. On the contrary, the advantage of the single-leaf method is its convenience and ease of measurement, and it can be flexibly moved in the measurement site. Therefore, in this study, we compare measurements of the whole-plant and singleleaf method on strawberry plants (Fragaria ananassa Duch.) grown under plant factory conditions to provide an overview of measurement methods for this plant species. The strawberry is a small herbaceous species with high economic values and convenient for the cultivation and measurement of photosynthesis.","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2021-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"44991164","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
This world is dependent on fossil fuel and there are various environmental problems caused by human activities such as global warming and pollution from municipal, industrial and agricultural waste. It is necessary for sustainable development to treat wastes adequately and to develop renewable energy. Utilization of biomass wastes has attracted a lot of interest because it is a way of waste management and also a source of renewable energy. Anaerobic digestion is one of them and has high potential to produce energy (Noike et al., 2009; Ghosh et al., 1975). Processing methods of anaerobic digestion are classified by solid content of feedstock and fermentation temperature (IEA BIOENERGY, 2001). The dry thermophilic anaerobic digestion is expected to be suitable in Japan because it occurs a small amount of digestate. Anaerobic digestion is also sorted out by the used feedstock. Anaerobic co-digestion, that is the process using the feedstock made from several kinds of substrates, has some advantages to anaerobic digestion from single substrate due to be able to adjust component of feedstock. Nakajima showed that anaerobic co-digestion from food waste with rich nitrogen and paper with rich carbon improves biogas generation because the C/N ratio of the feedstock is optimized (Nakajima et al., 2016). Food waste and paper constitute the second and third largest unused biomass waste in Japan (Excerpts from “Biomass Nippon Strategy”, Cabinet Decision, March 31, 2006). The efficient recycling method of these waste has been required to achieve sustainable development and the dry thermophilic anaerobic co-digestion is one of the important options. Although anaerobic digestion has many advantages such as the simultaneous treatment of waste, the utilization of digestate as a fertilizer and the robustness to the environment, it is not popular in Japan. There is the problem that reaction intermediates of anaerobic digestion including volatile fatty acid (VFA) and ammonia cause inhibition of methanogenesis easily. Overloading of organic matter leads to the accumulation of reaction intermediates and results in failure of the process. In spite of the biological vulnerability, anaerobic digestion has the robustness to the environment because the process proceeds in the closed reactor. Anaerobic digestion could play the role of supply and demand adjustment in the energy mix with environmental dependent renewable energies like wind and solar power. The numerical optimization of organic loading rate (OLR) has been studied for various purposes. MendezAcosta regulated the VFA concentration and total alkalinity (TA) to improve the stability of anaerobic digestion process with the dynamical model (Mendez-Acosta et al., 2016). Mauky developed the feeding management to compensate the divergence between supply and demand energy with ADM1 (Mauky et al., 2016; Batstone et al., 2002). The used models in these studies were proper for each control strategies (e.g. Mendez-Acosta set
这个世界依赖于化石燃料,人类活动造成了各种环境问题,如全球变暖和城市、工业和农业废物的污染。充分处理废物和开发可再生能源是可持续发展的需要。生物质废弃物的利用已经引起了人们的极大兴趣,因为它是一种废弃物管理的方式,也是可再生能源的来源。厌氧消化就是其中之一,具有很高的能量产生潜力(Noike et al., 2009;Ghosh et al., 1975)。厌氧消化的处理方法根据原料的固体含量和发酵温度进行分类(IEA BIOENERGY, 2001)。干式嗜热厌氧消化由于发生的消化量少,预计在日本是合适的。厌氧消化也被用过的原料分类。厌氧共消化是一种利用多种底物制成的原料进行厌氧消化的工艺,由于可以调节原料的成分,因此与单一底物厌氧消化相比具有一定的优势。Nakajima研究表明,由于优化了原料的C/N比,富氮食物垃圾和富碳纸张的厌氧共消化提高了沼气的产生(Nakajima et al., 2016)。食物垃圾和纸张是日本第二大和第三大未使用的生物质垃圾(摘自“日本生物质战略”,内阁决定,2006年3月31日)。为了实现可持续发展,需要有效地回收利用这些废物,而干法嗜热厌氧共消化是重要的选择之一。虽然厌氧消化具有垃圾同时处理、消化液作为肥料利用、对环境的稳健性等诸多优点,但在日本并不普及。厌氧消化的反应中间体挥发性脂肪酸(VFA)和氨容易抑制产甲烷。有机质超载会导致反应中间体的积累,导致反应过程的失败。尽管厌氧消化具有生物脆弱性,但由于厌氧消化过程是在封闭反应器中进行的,因此对环境具有鲁棒性。厌氧消化可以与风能和太阳能等环境依赖型可再生能源一起在能源结构中发挥供需调节作用。有机载荷率(OLR)的数值优化研究有多种用途。MendezAcosta通过动态模型调节VFA浓度和总碱度(TA)来提高厌氧消化过程的稳定性(Mendez-Acosta et al., 2016)。Mauky开发了喂养管理,以补偿ADM1的供需能量差异(Mauky et al., 2016;Batstone et al., 2002)。这些研究中使用的模型适用于每种控制策略(例如,Mendez-Acosta建立了一个关于TA的状态变量,Mauky使用大大简化的ADM1来预测每日沼气产量)。本研究旨在使厌氧消化过程稳定、高产
{"title":"Development of an Efficient Anaerobic Co-digestion Process for Biogas from Food Waste and Paper","authors":"N. Shimizu, Kazuto Yoshida","doi":"10.2525/ecb.59.165","DOIUrl":"https://doi.org/10.2525/ecb.59.165","url":null,"abstract":"This world is dependent on fossil fuel and there are various environmental problems caused by human activities such as global warming and pollution from municipal, industrial and agricultural waste. It is necessary for sustainable development to treat wastes adequately and to develop renewable energy. Utilization of biomass wastes has attracted a lot of interest because it is a way of waste management and also a source of renewable energy. Anaerobic digestion is one of them and has high potential to produce energy (Noike et al., 2009; Ghosh et al., 1975). Processing methods of anaerobic digestion are classified by solid content of feedstock and fermentation temperature (IEA BIOENERGY, 2001). The dry thermophilic anaerobic digestion is expected to be suitable in Japan because it occurs a small amount of digestate. Anaerobic digestion is also sorted out by the used feedstock. Anaerobic co-digestion, that is the process using the feedstock made from several kinds of substrates, has some advantages to anaerobic digestion from single substrate due to be able to adjust component of feedstock. Nakajima showed that anaerobic co-digestion from food waste with rich nitrogen and paper with rich carbon improves biogas generation because the C/N ratio of the feedstock is optimized (Nakajima et al., 2016). Food waste and paper constitute the second and third largest unused biomass waste in Japan (Excerpts from “Biomass Nippon Strategy”, Cabinet Decision, March 31, 2006). The efficient recycling method of these waste has been required to achieve sustainable development and the dry thermophilic anaerobic co-digestion is one of the important options. Although anaerobic digestion has many advantages such as the simultaneous treatment of waste, the utilization of digestate as a fertilizer and the robustness to the environment, it is not popular in Japan. There is the problem that reaction intermediates of anaerobic digestion including volatile fatty acid (VFA) and ammonia cause inhibition of methanogenesis easily. Overloading of organic matter leads to the accumulation of reaction intermediates and results in failure of the process. In spite of the biological vulnerability, anaerobic digestion has the robustness to the environment because the process proceeds in the closed reactor. Anaerobic digestion could play the role of supply and demand adjustment in the energy mix with environmental dependent renewable energies like wind and solar power. The numerical optimization of organic loading rate (OLR) has been studied for various purposes. MendezAcosta regulated the VFA concentration and total alkalinity (TA) to improve the stability of anaerobic digestion process with the dynamical model (Mendez-Acosta et al., 2016). Mauky developed the feeding management to compensate the divergence between supply and demand energy with ADM1 (Mauky et al., 2016; Batstone et al., 2002). The used models in these studies were proper for each control strategies (e.g. Mendez-Acosta set ","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2021-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"48897904","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
K. Zushi, Kan Tsutsuki, Hiromi Takahashi, M. Kirimura
Strawberry (Fragaria ananassa Duch.) is a rich source of bioactive compounds, including ascorbic acid (ASA), and polyphenols, such as anthocyanins and phenolic acids, most of which exhibit high antioxidant activities both in vitro and in vivo (Giampieri et al., 2012). As antioxidant compounds are associated with health benefits, the dietary intake of strawberry is highly recommended (Hannum, 2004; Cervantes et al., 2019). However, in the strawberry fruit, the content of antioxidant compounds varies because of genetics, environmental factors, and cultural practices. Previously, several studies on strawberry focused on the effects of environmental factors, such as harvest season (Choi et al., 2016), air temperature (Balasooriya et al., 2019; Shin et al., 2007; Sun et al., 2012), and light-related factors, such as light intensity, light duration, and ultraviolet (UV) exposure (Palmieri et al., 2017; Cervantes et al., 2019), on antioxidant compounds. In general, environmental conditions such as air temperature and irradiation have great impacts on plant growth because of changes in the photosynthetic apparatus, such as the photoinhibition of photosystem II (PSII) (Xu et al., 2020). Changes in the photosynthetic apparatus affect antioxidant metabolism through the generation of reactive oxygen species in photosynthesizing tissues (Hajiboland, 2014), which affect plant growth and/or photosynthetic performance, leading to changes in the level of antioxidant compounds. However, the effects of plant growth and photosynthetic performance on fruit antioxidant compounds have not yet been investigated. Therefore, to enhance the level of antioxidant compounds in the strawberry fruit, it is necessary to understand the interactions of antioxidant compounds with plant growth and photosynthetic performance. A correlation network analysis can be used widely to visualize interactions among various factors (Newman, 2003). From the agricultural viewpoint, the correlation network analysis of plant metabolism can provide key insights into biochemical processes and their regulation (Toubiana et al., 2013). Previously, correlation network analysis has been used to perform metabolic data analysis of several horticultural crops, such as tomato (DiLeo et al., 2011; Zushi and Matsuzoe, 2011, 2015), pepper (Silva et al., 2016), and strawberry (Fait et al., 2008). In these studies, the correlation network and its structure have been characterized extensively in efforts to elucidate the design principles of metabolic interactions. For example, in strawberry fruit, the correlation network suggested that metabolism is
草莓(Fragaria ananassa Duch.)含有丰富的生物活性化合物,包括抗坏血酸(ASA)和多酚类物质,如花青素和酚酸,其中大多数在体内和体外都具有很高的抗氧化活性(Giampieri et al., 2012)。由于抗氧化化合物与健康益处相关,因此强烈建议从饮食中摄入草莓(Hannum, 2004;塞万提斯等人,2019)。然而,在草莓果实中,抗氧化化合物的含量因遗传、环境因素和文化习俗而异。此前,一些关于草莓的研究主要集中在环境因素的影响上,如收获季节(Choi等人,2016)、气温(Balasooriya等人,2019;Shin et al., 2007;Sun et al., 2012),以及光相关因素,如光强度、光持续时间和紫外线(UV)暴露(Palmieri et al., 2017;塞万提斯等人,2019),研究抗氧化化合物。一般来说,由于光合机构的变化,如光系统II (PSII)的光抑制,气温和辐照等环境条件对植物生长有很大影响(Xu et al., 2020)。光合机构的变化通过在光合作用组织中产生活性氧来影响抗氧化代谢(Hajiboland, 2014),从而影响植物生长和/或光合性能,导致抗氧化化合物水平的变化。然而,植物生长和光合性能对果实抗氧化化合物的影响尚未研究。因此,为了提高草莓果实中抗氧化物质的含量,有必要了解抗氧化物质与植物生长和光合性能的相互作用。相关网络分析可以广泛用于可视化各种因素之间的相互作用(Newman, 2003)。从农业的角度来看,植物代谢的相关网络分析可以为生物化学过程及其调控提供关键见解(Toubiana et al., 2013)。此前,相关网络分析已被用于对番茄等几种园艺作物进行代谢数据分析(DiLeo et al., 2011;Zushi和Matsuzoe, 2011, 2015),辣椒(Silva等人,2016)和草莓(Fait等人,2008)。在这些研究中,相关网络及其结构被广泛表征,以阐明代谢相互作用的设计原则。例如,在草莓果实中,相关网络表明代谢是
{"title":"Correlation Network Analysis Visually Identifies Interactions of Antioxidant Compounds with Plant Growth, Leaf Photosynthetic Performance, and Agronomic Quality in Strawberry","authors":"K. Zushi, Kan Tsutsuki, Hiromi Takahashi, M. Kirimura","doi":"10.2525/ecb.59.147","DOIUrl":"https://doi.org/10.2525/ecb.59.147","url":null,"abstract":"Strawberry (Fragaria ananassa Duch.) is a rich source of bioactive compounds, including ascorbic acid (ASA), and polyphenols, such as anthocyanins and phenolic acids, most of which exhibit high antioxidant activities both in vitro and in vivo (Giampieri et al., 2012). As antioxidant compounds are associated with health benefits, the dietary intake of strawberry is highly recommended (Hannum, 2004; Cervantes et al., 2019). However, in the strawberry fruit, the content of antioxidant compounds varies because of genetics, environmental factors, and cultural practices. Previously, several studies on strawberry focused on the effects of environmental factors, such as harvest season (Choi et al., 2016), air temperature (Balasooriya et al., 2019; Shin et al., 2007; Sun et al., 2012), and light-related factors, such as light intensity, light duration, and ultraviolet (UV) exposure (Palmieri et al., 2017; Cervantes et al., 2019), on antioxidant compounds. In general, environmental conditions such as air temperature and irradiation have great impacts on plant growth because of changes in the photosynthetic apparatus, such as the photoinhibition of photosystem II (PSII) (Xu et al., 2020). Changes in the photosynthetic apparatus affect antioxidant metabolism through the generation of reactive oxygen species in photosynthesizing tissues (Hajiboland, 2014), which affect plant growth and/or photosynthetic performance, leading to changes in the level of antioxidant compounds. However, the effects of plant growth and photosynthetic performance on fruit antioxidant compounds have not yet been investigated. Therefore, to enhance the level of antioxidant compounds in the strawberry fruit, it is necessary to understand the interactions of antioxidant compounds with plant growth and photosynthetic performance. A correlation network analysis can be used widely to visualize interactions among various factors (Newman, 2003). From the agricultural viewpoint, the correlation network analysis of plant metabolism can provide key insights into biochemical processes and their regulation (Toubiana et al., 2013). Previously, correlation network analysis has been used to perform metabolic data analysis of several horticultural crops, such as tomato (DiLeo et al., 2011; Zushi and Matsuzoe, 2011, 2015), pepper (Silva et al., 2016), and strawberry (Fait et al., 2008). In these studies, the correlation network and its structure have been characterized extensively in efforts to elucidate the design principles of metabolic interactions. For example, in strawberry fruit, the correlation network suggested that metabolism is","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2021-07-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"44730751","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
The exhaustion of finite fossil fuels and the impact of their mass use on the environment are of global concern. Attention is focused on the use of renewable energies such as sun, wind power and geothermal heat. The use of these energies is also desired in greenhouse horticulture, where large amounts of electric power and fossil fuels are employed (Kawamura et al., 2006; Fukui et al., 2009). Examples of using renewable energy in agricultural production are heating the inside of greenhouses through biomass combustion (Kawamura et al., 2006) and crop preservation using snow (Nakamura and Osada, 2001; Ishihara et al., 2005; Nikaido et al., 2014). However, using natural energy in agricultural production can be difficult as its abundance and form depending on geography and season. Previous research suggests that its unstable nature and energy smallness can be compensated by combining multiple energy types and inputting it locally (Angelis-Dimakis et al., 2011). In recent years, the demand for Western vegetables, including witloof chicory (Cichorium intybus L.), has increased in Japan (Ohtani, 2004), where almost all witloof chicory to date has been imported. However, doing so is expensive, and as such, domestic production of witloof chicory is anticipated for introduction to the Japanese market at a low price and high quality. Cultivation of witloof chicory comprises two stages: firstly, plant growing and harvesting of chicory roots in an open field and, secondly, implementing forcing culture of harvested roots for production of etiolated heads. Chicory roots are generally stored at a low temperature of roughly 0 °C and high relative humidity until forcing culture is implemented. The storage period is cultivar-dependent (König and Combrink, 2002). Forcing culture is generally carried out by employing high-density planting in a dark space under a controlled and constant temperature of 14 to 18 °C (Morishita, 1988). High temperatures cause rapid growth of loose and elongated heads, whereas low temperatures reduce growth rate and produce shorter and tighter heads (Ryder, 1998). Since loose, irregular shaped or small heads are not marketable (Sterrett and Savage, 1989), temperature control within a suitable range is important in forcing culture. In order to produce etiolated heads throughout the year, special equipment is needed for controlling the temperature within a suitable range in Japan (14 to 18 °C), particularly in summer and winter. In the commercial production of chicory heads, electrical air conditioning systems are applied in the forcing room, but this is a costly process. Since forcing culture can be carried out in an enclosed and narrow space, it is potentially viable to control temperature using natural heat sources, despite the limited energy density, compared to fossil fuels. Several studies have explored the feasibility of geo-
{"title":"Utilization of Snow and Geothermal Cold Heat for Temperature Control and Head Production in Witloof Chicory Hydroponic Forcing Culture in Summer","authors":"T. Uno, T. Kumano, H. Araki","doi":"10.2525/ecb.59.125","DOIUrl":"https://doi.org/10.2525/ecb.59.125","url":null,"abstract":"The exhaustion of finite fossil fuels and the impact of their mass use on the environment are of global concern. Attention is focused on the use of renewable energies such as sun, wind power and geothermal heat. The use of these energies is also desired in greenhouse horticulture, where large amounts of electric power and fossil fuels are employed (Kawamura et al., 2006; Fukui et al., 2009). Examples of using renewable energy in agricultural production are heating the inside of greenhouses through biomass combustion (Kawamura et al., 2006) and crop preservation using snow (Nakamura and Osada, 2001; Ishihara et al., 2005; Nikaido et al., 2014). However, using natural energy in agricultural production can be difficult as its abundance and form depending on geography and season. Previous research suggests that its unstable nature and energy smallness can be compensated by combining multiple energy types and inputting it locally (Angelis-Dimakis et al., 2011). In recent years, the demand for Western vegetables, including witloof chicory (Cichorium intybus L.), has increased in Japan (Ohtani, 2004), where almost all witloof chicory to date has been imported. However, doing so is expensive, and as such, domestic production of witloof chicory is anticipated for introduction to the Japanese market at a low price and high quality. Cultivation of witloof chicory comprises two stages: firstly, plant growing and harvesting of chicory roots in an open field and, secondly, implementing forcing culture of harvested roots for production of etiolated heads. Chicory roots are generally stored at a low temperature of roughly 0 °C and high relative humidity until forcing culture is implemented. The storage period is cultivar-dependent (König and Combrink, 2002). Forcing culture is generally carried out by employing high-density planting in a dark space under a controlled and constant temperature of 14 to 18 °C (Morishita, 1988). High temperatures cause rapid growth of loose and elongated heads, whereas low temperatures reduce growth rate and produce shorter and tighter heads (Ryder, 1998). Since loose, irregular shaped or small heads are not marketable (Sterrett and Savage, 1989), temperature control within a suitable range is important in forcing culture. In order to produce etiolated heads throughout the year, special equipment is needed for controlling the temperature within a suitable range in Japan (14 to 18 °C), particularly in summer and winter. In the commercial production of chicory heads, electrical air conditioning systems are applied in the forcing room, but this is a costly process. Since forcing culture can be carried out in an enclosed and narrow space, it is potentially viable to control temperature using natural heat sources, despite the limited energy density, compared to fossil fuels. Several studies have explored the feasibility of geo-","PeriodicalId":85505,"journal":{"name":"Seibutsu kankyo chosetsu. [Environment control in biology","volume":" ","pages":""},"PeriodicalIF":0.0,"publicationDate":"2021-07-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":null,"resultStr":null,"platform":"Semanticscholar","paperid":"43197158","PeriodicalName":null,"FirstCategoryId":null,"ListUrlMain":null,"RegionNum":0,"RegionCategory":"","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":"","EPubDate":null,"PubModel":null,"JCR":null,"JCRName":null,"Score":null,"Total":0}
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