The Production of Bacterial Cellulose by Co-Cultivation of Komagataeibacter sucrofermentans with Dextran Producers Leuconostoc mesenteroides and Xanthan Xanthomonas campestris

N. Nazarova, E. Liyaskina, V. Revin
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In addition, many biosynthetic genes remain silent and not expressed in vitro, thereby severely limiting the chemical diversity of microbial compounds that can be obtained by fermentation. In contrast, the co-cultivation of two or more different microorganisms mimics a real \"situation\" where microorganisms coexist in complex microbial communities. It has been proven that competition or antagonism occurring within co-cultivation leads to a significant increase in the existing compounds and / or accumulation of new compounds which are not found in axial cultures of the producer strain. The purpose of this study is to investigate cocultivation as a way to increase the yield of BC during the cultivation of BC producers with other polysaccharide-forming strains. The strain of Komagataeibacter sucrofermentans B-11267 was used as a BC producer, Xanthomonas campestris was used as a xanthan producer, and Leuconostoc mesenteroides was used as a dextran producer. The cultivation was carried out under dynamic conditions on a medium with molasses. The polysaccharide yield was expressed as the absolute dry weight of the polymers per unit volume of the culture medium. We have studied the BC morphology using atomic force microscopy (AFM) and FTIR spectroscopy. Crystallinity was checked by X-ray diffraction analysis. The interest in BC makes it necessary to synthesize it in large quantities on an industrial scale. The problem of increasing productivity was solved by co-cultivating the BC producer Komagataeibacter sucrofermentans with the producers of dextran Leuconostoc mesenteroides and xanthan Xanthomonas campestris, since the addition of water-soluble polysaccharides is known to increase the viscosity of the medium and facilitate the dispersion of bacterial cellulose granules. Thereby increasing the number of free cells, which can accelerate sugar consumption and polymer formation. At the first stage of the study, the most optimal conditions for co-cultivation of the BC producer with the producers of xanthan and dextran were selected, namely, the optimal pH value of the medium. Monoculture of bacteria X. campestris, L. mesenteroides, and K. sucrofermentans was carried out at different pH values (See Fig. 1-3). Based on the data obtained, we can say that the most optimal pH value for co-cultivation of microorganisms is pH 5.0. In this regard, at the second stage of this study, we carried out joint cultivation of the BC producer strain K. sucrofermentans with the xanthan and dextran producers X. campestris and L. mesenteroides, respectively, on molasses medium. From the data presented (See Fig. 4), it can be seen that the largest amount of polysaccharide is formed on the third day during cocultivation of the BC producer and the dextran producer. The amount of BC was 5.99 ± 0.02 g/l, which is two and a half times higher than the amount of polymer formed during monocultivation of a BC producer (2.25 ± 0.05 g/l). Co-cultivation of the BC producer strain with the xanthan producer did not lead to an increase in the polysaccharide yield. Therefore, no further study of co-cultivation of these microorganisms was carried out. To assess the success of the joint cultivation of BC and dextran producer strains and investigate the properties of the obtained polysaccharide, studies using AFM, FTIR spectroscopy, and X-ray structural analysis were carried out. The surface relief of the obtained BC was studied using the AFM method (See Fig. 7). Analysis of the AFM images showed the presence of an association of K. sucrofermentans and L. mesenteroides cells in the BC. Also, the obtained BC was investigated using the method of FTIR spectroscopy (See Fig. 8). The obtained IR spectra show similarity of the detected peaks with the literature data of peaks corresponding to BC. To determine the degree of crystallinity, the structure of cellulose was studied by X-ray structural analysis (See Fig. 9). The degree of crystallinity of the studied cellulose samples is 64% and 32% with monocultivation of K. sucrofermentans and co-cultivation of K. sucrofermentans and L. mesenteroides, respectively. The article contains 9 Figures, 1 Table, 37 References.","PeriodicalId":37153,"journal":{"name":"Vestnik Tomskogo Gosudarstvennogo Universiteta-Biologiya","volume":"31 1","pages":""},"PeriodicalIF":0.4000,"publicationDate":"2022-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Vestnik Tomskogo Gosudarstvennogo Universiteta-Biologiya","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.17223/19988591/60/2","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"BIOLOGY","Score":null,"Total":0}
引用次数: 1

Abstract

Bacterial cellulose (BC) is an extracellular product of bacterial metabolism. Like plant cellulose, BC has the same molecular formula but its structure is significantly different. Due to its unique properties (high degree of crystallinity, purity, good water-holding capacity), BC is widely used in many areas of human life. However, despite all the advantages of BC over plant polymers, its production is a relatively expensive process. Thus, one of the ways to increase the polymer yield can be to jointly cultivate a BC producer strain with other polysaccharide producers. The positive effect of some water-soluble polysaccharides on the BC output is known from the literature data. In addition, many biosynthetic genes remain silent and not expressed in vitro, thereby severely limiting the chemical diversity of microbial compounds that can be obtained by fermentation. In contrast, the co-cultivation of two or more different microorganisms mimics a real "situation" where microorganisms coexist in complex microbial communities. It has been proven that competition or antagonism occurring within co-cultivation leads to a significant increase in the existing compounds and / or accumulation of new compounds which are not found in axial cultures of the producer strain. The purpose of this study is to investigate cocultivation as a way to increase the yield of BC during the cultivation of BC producers with other polysaccharide-forming strains. The strain of Komagataeibacter sucrofermentans B-11267 was used as a BC producer, Xanthomonas campestris was used as a xanthan producer, and Leuconostoc mesenteroides was used as a dextran producer. The cultivation was carried out under dynamic conditions on a medium with molasses. The polysaccharide yield was expressed as the absolute dry weight of the polymers per unit volume of the culture medium. We have studied the BC morphology using atomic force microscopy (AFM) and FTIR spectroscopy. Crystallinity was checked by X-ray diffraction analysis. The interest in BC makes it necessary to synthesize it in large quantities on an industrial scale. The problem of increasing productivity was solved by co-cultivating the BC producer Komagataeibacter sucrofermentans with the producers of dextran Leuconostoc mesenteroides and xanthan Xanthomonas campestris, since the addition of water-soluble polysaccharides is known to increase the viscosity of the medium and facilitate the dispersion of bacterial cellulose granules. Thereby increasing the number of free cells, which can accelerate sugar consumption and polymer formation. At the first stage of the study, the most optimal conditions for co-cultivation of the BC producer with the producers of xanthan and dextran were selected, namely, the optimal pH value of the medium. Monoculture of bacteria X. campestris, L. mesenteroides, and K. sucrofermentans was carried out at different pH values (See Fig. 1-3). Based on the data obtained, we can say that the most optimal pH value for co-cultivation of microorganisms is pH 5.0. In this regard, at the second stage of this study, we carried out joint cultivation of the BC producer strain K. sucrofermentans with the xanthan and dextran producers X. campestris and L. mesenteroides, respectively, on molasses medium. From the data presented (See Fig. 4), it can be seen that the largest amount of polysaccharide is formed on the third day during cocultivation of the BC producer and the dextran producer. The amount of BC was 5.99 ± 0.02 g/l, which is two and a half times higher than the amount of polymer formed during monocultivation of a BC producer (2.25 ± 0.05 g/l). Co-cultivation of the BC producer strain with the xanthan producer did not lead to an increase in the polysaccharide yield. Therefore, no further study of co-cultivation of these microorganisms was carried out. To assess the success of the joint cultivation of BC and dextran producer strains and investigate the properties of the obtained polysaccharide, studies using AFM, FTIR spectroscopy, and X-ray structural analysis were carried out. The surface relief of the obtained BC was studied using the AFM method (See Fig. 7). Analysis of the AFM images showed the presence of an association of K. sucrofermentans and L. mesenteroides cells in the BC. Also, the obtained BC was investigated using the method of FTIR spectroscopy (See Fig. 8). The obtained IR spectra show similarity of the detected peaks with the literature data of peaks corresponding to BC. To determine the degree of crystallinity, the structure of cellulose was studied by X-ray structural analysis (See Fig. 9). The degree of crystallinity of the studied cellulose samples is 64% and 32% with monocultivation of K. sucrofermentans and co-cultivation of K. sucrofermentans and L. mesenteroides, respectively. The article contains 9 Figures, 1 Table, 37 References.
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与右旋糖酐产菌肠系膜白菌和黄原菌共培养细菌纤维素的研究
细菌纤维素(BC)是细菌代谢的胞外产物。与植物纤维素一样,BC分子式相同,但结构有明显不同。由于其独特的性质(结晶度高,纯度高,保水能力好),BC被广泛应用于人类生活的许多领域。然而,尽管BC比植物聚合物有很多优点,它的生产是一个相对昂贵的过程。因此,提高聚合物产量的方法之一是与其他多糖产生菌共同培养BC产生菌。一些水溶性多糖对BC产量的积极影响是从文献数据中得知的。此外,许多生物合成基因在体外保持沉默且不表达,从而严重限制了可通过发酵获得的微生物化合物的化学多样性。相反,两种或多种不同微生物的共同培养模拟了微生物在复杂微生物群落中共存的真实“情况”。已经证明,在共培养中发生的竞争或拮抗导致现有化合物的显著增加和/或新化合物的积累,而这些化合物在生产菌株的轴向培养中没有发现。本研究的目的是探讨在BC生产者的培养过程中,与其他产生多糖的菌株共培养以提高BC的产量。以蔗糖发酵komagataeibactersucrofermentans B-11267菌株为BC产生菌,以油菜黄单胞菌(Xanthomonas campestris)为黄原胶产生菌,以肠系膜leconostoc为葡聚糖产生菌。在含糖蜜的培养基上进行动态培养。多糖得率表示为每单位体积培养基中聚合物的绝对干重。我们用原子力显微镜(AFM)和红外光谱(FTIR)研究了BC的形貌。结晶度通过x射线衍射分析进行检验。对BC的兴趣使得有必要在工业规模上大量合成它。提高生产效率的问题是通过与葡聚糖、肠系膜Leuconostoc肠系膜黄单胞菌(Xanthomonas campestris)、黄原菌(Xanthomonas campestris)共同培养BC产菌komagataeibacterium sucrofermentans来解决的,因为已知水溶性多糖的添加可以增加培养基的粘度,促进细菌纤维素颗粒的分散。从而增加游离细胞的数量,这可以加速糖的消耗和聚合物的形成。在研究的第一阶段,选择了BC产菌与黄原胶和葡聚糖产菌共培养的最佳条件,即培养基的最佳pH值。在不同的pH值下进行单培养的campestris、肠系膜乳杆菌和sucrofermentans细菌(见图1-3)。根据所获得的数据,我们可以说,微生物共培养的最佳pH值为pH 5.0。因此,在本研究的第二阶段,我们在糖蜜培养基上分别与黄原胶和葡聚糖的产生菌X. campestris和L. mesenteroides进行了BC产生菌K. sucrofermentans的联合培养。从所提供的数据(图4)可以看出,BC产菌与葡聚糖产菌共培养的第3天,多糖的形成量最大。BC的量为5.99±0.02 g/l,是BC生产者单次培养时聚合物形成量(2.25±0.05 g/l)的2.5倍。BC产生菌与黄原胶产生菌的共培养并未导致多糖产量的增加。因此,没有对这些微生物的共培养进行进一步的研究。为了评估BC和葡聚糖产生菌的联合培养是否成功,并研究获得的多糖的性质,使用AFM, FTIR光谱和x射线结构分析进行了研究。使用AFM方法研究所得BC的表面浮雕(见图7)。AFM图像分析显示,BC中存在sucrofermentans和肠系膜乳杆菌细胞的关联。同时,利用FTIR光谱方法对所得BC进行了研究(见图8)。所得的红外光谱显示,检测峰与BC对应峰的文献数据相似。为了确定纤维素的结晶度,通过x射线结构分析对纤维素的结构进行了研究(见图9)。研究的纤维素样品的结晶度分别为64%和32%,分别为单种培养、双歧杆菌培养和肠系膜乳杆菌培养。全文共9图,1表,37参考文献。
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