{"title":"表面相关的植物细胞培养","authors":"A. Mehring, J. Stiefelmaier, R. Ulber","doi":"10.5194/biofilms9-79","DOIUrl":null,"url":null,"abstract":"<p>Biofilms are typically characterized as a consortium of microorganisms, which adhere to each other and often to surfaces. This adhesion is realized by extracellular polymeric substances (EPS), which are secreted by the microorganisms and mainly consist of water, polysaccharides, proteins and lipids as well as nucleic acids and lysis products [1]. Although cultured plant cells are not typically considered biofilms, parallels can be found in the properties of plant calli. These callus cells tend to form cohesive aggregates, owing to their extracellular matrix, and often strongly adhere to the agar plates they are kept on. The extracellular matrix of plant cells is mainly composed of structural polysaccharides, such as xyloglucans, arabinogalactans [2], homogalacturonan and extensins [3] among others. Cultured plant cells were found to adhere to surfaces before [4]. Surface-associated plant cell culture may have potential in a (semi‑)continuous cultivation including product secretion, as was shown in principle for alginate-embedded plant cells [5]. For cyanobacterial biofilms, an efficient strategy for EPS extraction was recently developed [6]. The transferability of these protocols to biofilm-like growing plant calli of Ocimum basilicum is currently being investigated. Subsequently, the composition of the extracellular matrix extracted from cultured O. basilicum cells is of interest. Furthermore, the adhesive properties of O. basilicum suspension cultures to microstructured surfaces and the potential role of the extracellular matrix are under investigation. An investigation of culture properties in an aerosol photobioreactor [7] is planned as well.</p>\n<p>This project is financially supported by the German research foundation (DFG, project number SFB 926-C03).</p>\n<p> </p>\n<p>References:</p>\n<p>[1]      H. C. Flemming, T. R. Neu, and D. J. Wozniak, “The EPS matrix: The ‘House of Biofilm Cells,’” J. Bacteriol., vol. 189, no. 22, pp. 7945–7947, 2007.</p>\n<p>[2]      I. M. Sims, K. Middleton, A. G. Lane, A. J. Cairns, and A. Bacic, “Characterisation of extracellular polysaccharides from suspension cultures of members of the Poaceae,” Planta, vol. 210, no. 2, pp. 261–268, Jan. 2000.</p>\n<p>[3]      M. Popielarska-Konieczna, K. Sala, M. Abdullah, M. Tuleja, and E. Kurczyńska, “Extracellular matrix and wall composition are diverse in the organogenic and non-organogenic calli of Actinidia arguta,” Plant Cell Rep., no. 0123456789, 2020.</p>\n<p>[4]      R. J. Robins, D. O. Hall, D. ‐J Shi, R. J. Turner, and M. J. C. Rhodes, “Mucilage acts to adhere cyanobacteria and cultured plant cells to biological and inert surfaces,” FEMS Microbiol. Lett., vol. 34, no. 2, pp. 155–160, 1986.</p>\n<p>[5]      Y. Kobayashi, H. Fukui, and M. Tabata, “Berberine production by batch and semi-continuous cultures of immobilized Thalictrum cells in an improved bioreactor,” Plant Cell Rep., vol. 7, no. 4, pp. 249–252, 1988.</p>\n<p>[6]      D. Strieth, J. Stiefelmaier, B. Wrabl et al., “A new strategy for a combined isolation of EPS and pigments from cyanobacteria,” J. Appl. Phycol., no. Fromme 2008, Feb. 2020.</p>\n<p>[7]        S. Kuhne, D. Strieth, M. Lakatos, K. Muffler, and R. Ulber, “A new photobioreactor concept enabling the production of desiccation induced biotechnological products using terrestrial cyanobacteria,” J. Biotechnol., vol. 192, no. Part A, pp. 28–33, 2014.</p>","PeriodicalId":87392,"journal":{"name":"Biofilms","volume":" ","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2020-07-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Surface-associated plant cell culture\",\"authors\":\"A. Mehring, J. Stiefelmaier, R. Ulber\",\"doi\":\"10.5194/biofilms9-79\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Biofilms are typically characterized as a consortium of microorganisms, which adhere to each other and often to surfaces. This adhesion is realized by extracellular polymeric substances (EPS), which are secreted by the microorganisms and mainly consist of water, polysaccharides, proteins and lipids as well as nucleic acids and lysis products [1]. Although cultured plant cells are not typically considered biofilms, parallels can be found in the properties of plant calli. These callus cells tend to form cohesive aggregates, owing to their extracellular matrix, and often strongly adhere to the agar plates they are kept on. The extracellular matrix of plant cells is mainly composed of structural polysaccharides, such as xyloglucans, arabinogalactans [2], homogalacturonan and extensins [3] among others. Cultured plant cells were found to adhere to surfaces before [4]. Surface-associated plant cell culture may have potential in a (semi‑)continuous cultivation including product secretion, as was shown in principle for alginate-embedded plant cells [5]. For cyanobacterial biofilms, an efficient strategy for EPS extraction was recently developed [6]. The transferability of these protocols to biofilm-like growing plant calli of Ocimum basilicum is currently being investigated. Subsequently, the composition of the extracellular matrix extracted from cultured O. basilicum cells is of interest. Furthermore, the adhesive properties of O. basilicum suspension cultures to microstructured surfaces and the potential role of the extracellular matrix are under investigation. An investigation of culture properties in an aerosol photobioreactor [7] is planned as well.</p>\\n<p>This project is financially supported by the German research foundation (DFG, project number SFB 926-C03).</p>\\n<p> </p>\\n<p>References:</p>\\n<p>[1]      H. C. Flemming, T. R. Neu, and D. J. Wozniak, “The EPS matrix: The ‘House of Biofilm Cells,’” J. Bacteriol., vol. 189, no. 22, pp. 7945–7947, 2007.</p>\\n<p>[2]      I. M. Sims, K. Middleton, A. G. Lane, A. J. Cairns, and A. Bacic, “Characterisation of extracellular polysaccharides from suspension cultures of members of the Poaceae,” Planta, vol. 210, no. 2, pp. 261–268, Jan. 2000.</p>\\n<p>[3]      M. Popielarska-Konieczna, K. Sala, M. Abdullah, M. Tuleja, and E. Kurczyńska, “Extracellular matrix and wall composition are diverse in the organogenic and non-organogenic calli of Actinidia arguta,” Plant Cell Rep., no. 0123456789, 2020.</p>\\n<p>[4]      R. J. Robins, D. O. Hall, D. ‐J Shi, R. J. Turner, and M. J. C. Rhodes, “Mucilage acts to adhere cyanobacteria and cultured plant cells to biological and inert surfaces,” FEMS Microbiol. Lett., vol. 34, no. 2, pp. 155–160, 1986.</p>\\n<p>[5]      Y. Kobayashi, H. Fukui, and M. Tabata, “Berberine production by batch and semi-continuous cultures of immobilized Thalictrum cells in an improved bioreactor,” Plant Cell Rep., vol. 7, no. 4, pp. 249–252, 1988.</p>\\n<p>[6]      D. Strieth, J. Stiefelmaier, B. Wrabl et al., “A new strategy for a combined isolation of EPS and pigments from cyanobacteria,” J. Appl. Phycol., no. Fromme 2008, Feb. 2020.</p>\\n<p>[7]        S. Kuhne, D. Strieth, M. Lakatos, K. Muffler, and R. Ulber, “A new photobioreactor concept enabling the production of desiccation induced biotechnological products using terrestrial cyanobacteria,” J. Biotechnol., vol. 192, no. 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引用次数: 0
摘要
生物膜的典型特征是微生物的联合体,它们相互粘附,经常附着在表面上。这种粘附是由微生物分泌的细胞外聚合物(EPS)来实现的,EPS主要由水、多糖、蛋白质和脂质以及核酸和裂解产物[1]组成。虽然培养的植物细胞通常不被认为是生物膜,但在植物愈伤组织的特性中可以发现相似之处。由于细胞外基质的作用,这些愈伤组织细胞倾向于形成有凝聚力的聚集体,并且经常强烈地粘附在它们所处的琼脂板上。植物细胞的胞外基质主要由结构多糖组成,如木葡聚糖、阿拉伯半乳聚糖[2]、均半乳聚糖[3]和伸展蛋白[3]等。培养的植物细胞在bb0之前就能粘附在表面。表面相关的植物细胞培养在(半‑)连续培养中可能具有潜力,包括产物分泌,正如藻酸盐包埋的植物细胞[5]的原理所示。对于蓝藻生物膜,最近开发了一种高效的EPS提取策略。目前正在研究这些方案在basilicum生物膜样生长植物愈伤组织中的可移植性。随后,从培养的O. basilicum细胞中提取的细胞外基质的组成令人感兴趣。此外,O. basilicum悬浮培养物对微结构表面的粘附性能和细胞外基质的潜在作用正在研究中。并计划对气溶胶光生物反应器[7]的培养特性进行研究。本项目由德国研究基金会(DFG,项目编号SFB 926-C03)资助。 参考文献:[1] H. C.弗莱明,T. R.纽和D. J.沃兹尼亚克,&# 8220;EPS矩阵:‘生物膜细胞之家,’”j . Bacteriol。,第189卷,第189期。22日,页。7945 & # 8211;7947年,2007年。[2]& # 160;& # 160;& # 160;& # 160;& # 160;I. M. Sims, K. Middleton, A. G. Lane, A. J. Cairns和A. Bacic, “从Poaceae成员的悬浮培养中提取细胞外多糖的特性,”《植物》,第210卷,第2期。2,页261 & # 8211;268年,2000年1月。[3]& # 160;& # 160;& # 160;& # 160;& # 160;M. Popielarska-Konieczna, K. Sala, M. Abdullah, M. Tuleja, and E. kurczye ńska, “猕桃有机和非有机愈伤组织细胞外基质和细胞壁组成不同,”植物细胞代表,不。0123456789, 2020。[4]& # 160;& # 160;& # 160;& # 160;& # 160;R. J. Robins, D. O. Hall, D. ‐J . Shi, R. J. Turner, and M. J. C. Rhodes, “粘液作用使蓝藻和培养的植物细胞粘附在生物和惰性表面上,”《。列托人。,第34卷,no。2,页155 & # 8211;160年,1986年。[5]& # 160;& # 160;& # 160;& # 160;& # 160;Y. Kobayashi, H. Fukui, and M. Tabata, “固定化Thalictrum细胞在改进的生物反应器中分批和半连续培养生产小檗碱,”植物细胞报,第7卷,第7期。4,页249 & # 8211;252年,1988年。[6]& # 160;& # 160;& # 160;& # 160;& # 160;D. Strieth, J. Stiefelmaier, B. Wrabl等,&# 8220;从蓝藻中联合分离EPS和色素的新策略,”j:。Phycol。,没有。Fromme 2008年,2020年2月。[7]& # 160;& # 160;& # 160;& # 160;& # 160;& # 160;& # 160;S. Kuhne, D. Strieth, M. Lakatos, K. Muffler, and R. Ulber, “利用陆生蓝藻生产干燥诱导生物技术产品的新光生物反应器概念,”生物科技j .》。,第192卷,第2号。A部分,pp. 28–33, 2014。
Biofilms are typically characterized as a consortium of microorganisms, which adhere to each other and often to surfaces. This adhesion is realized by extracellular polymeric substances (EPS), which are secreted by the microorganisms and mainly consist of water, polysaccharides, proteins and lipids as well as nucleic acids and lysis products [1]. Although cultured plant cells are not typically considered biofilms, parallels can be found in the properties of plant calli. These callus cells tend to form cohesive aggregates, owing to their extracellular matrix, and often strongly adhere to the agar plates they are kept on. The extracellular matrix of plant cells is mainly composed of structural polysaccharides, such as xyloglucans, arabinogalactans [2], homogalacturonan and extensins [3] among others. Cultured plant cells were found to adhere to surfaces before [4]. Surface-associated plant cell culture may have potential in a (semi‑)continuous cultivation including product secretion, as was shown in principle for alginate-embedded plant cells [5]. For cyanobacterial biofilms, an efficient strategy for EPS extraction was recently developed [6]. The transferability of these protocols to biofilm-like growing plant calli of Ocimum basilicum is currently being investigated. Subsequently, the composition of the extracellular matrix extracted from cultured O. basilicum cells is of interest. Furthermore, the adhesive properties of O. basilicum suspension cultures to microstructured surfaces and the potential role of the extracellular matrix are under investigation. An investigation of culture properties in an aerosol photobioreactor [7] is planned as well.
This project is financially supported by the German research foundation (DFG, project number SFB 926-C03).
References:
[1] H. C. Flemming, T. R. Neu, and D. J. Wozniak, “The EPS matrix: The ‘House of Biofilm Cells,’” J. Bacteriol., vol. 189, no. 22, pp. 7945–7947, 2007.
[2] I. M. Sims, K. Middleton, A. G. Lane, A. J. Cairns, and A. Bacic, “Characterisation of extracellular polysaccharides from suspension cultures of members of the Poaceae,” Planta, vol. 210, no. 2, pp. 261–268, Jan. 2000.
[3] M. Popielarska-Konieczna, K. Sala, M. Abdullah, M. Tuleja, and E. Kurczyńska, “Extracellular matrix and wall composition are diverse in the organogenic and non-organogenic calli of Actinidia arguta,” Plant Cell Rep., no. 0123456789, 2020.
[4] R. J. Robins, D. O. Hall, D. ‐J Shi, R. J. Turner, and M. J. C. Rhodes, “Mucilage acts to adhere cyanobacteria and cultured plant cells to biological and inert surfaces,” FEMS Microbiol. Lett., vol. 34, no. 2, pp. 155–160, 1986.
[5] Y. Kobayashi, H. Fukui, and M. Tabata, “Berberine production by batch and semi-continuous cultures of immobilized Thalictrum cells in an improved bioreactor,” Plant Cell Rep., vol. 7, no. 4, pp. 249–252, 1988.
[6] D. Strieth, J. Stiefelmaier, B. Wrabl et al., “A new strategy for a combined isolation of EPS and pigments from cyanobacteria,” J. Appl. Phycol., no. Fromme 2008, Feb. 2020.
[7] S. Kuhne, D. Strieth, M. Lakatos, K. Muffler, and R. Ulber, “A new photobioreactor concept enabling the production of desiccation induced biotechnological products using terrestrial cyanobacteria,” J. Biotechnol., vol. 192, no. Part A, pp. 28–33, 2014.
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