碳源和氮源对水母雪莲悬浮培养细胞生长和黄酮合成的影响

在MS培养基上进行水母雪莲(Saussurea medusa Maxim)细胞悬浮培养时研究了碳源和氮源的影响。结果表明碳源以蔗糖最适合,蔗糖浓度则以40g/L较好,细胞生长量干重为18.12g/L,总黄酮合成量达到1423.25mg/L。在培养过程中,水母雪莲细胞能够快速将蔗糖水解为葡萄糖和果糖,并首先利用葡萄糖。氮源总浓度(包括NH⁺₄和NO^-₃)为60～120mmol/L,NH⁺₄/NO^-₃比例为20/40有利于雪莲细胞生长和黄酮合成。用HPLC检测显示4′,5,7-三羟基3′,6-二甲氧基黄酮(Jaceosidin)和4′,5,7-三羟基-6-甲氧基黄酮(Hispidulin)2种黄酮的含量分别达到细胞干重的1.46%和0.010%     

自絮凝酵母SPSC01在组合反应器系统中酒精连续发酵的研究

建立了一套由四级磁力搅拌发酵罐串联组成、总有效容积4000mL的小型组合生物反应器系统 ,其中一级罐作为种子培养罐。以脱胚脱皮玉米粉双酶法制备的糖化液为种子培养基和发酵底物 ,进行了自絮凝颗粒酵母酒精连续发酵的研究。种子罐培养基还原糖浓度为100g L ,添加 (NH₄)₂HPO₄ 和KH₂PO₄ 各 20g L ,以0.017h^-1 的恒定稀释速率流加 ,并溢流至后续酒精发酵系统。发酵底物初始还原糖浓度 220g/L ,添加 (NH₄)₂HPO₄ 15g/L和KH₂PO₄2 5g/L ,流加至第一级发酵罐 ,稀释速率分别为 0.017、0.025、0.033、0.040和0.05 0h^-1。实验数据表明 ,自絮凝颗粒酵母在各发酵罐中呈部分固定化状态 ,在稀释速率0.040h^-1 条件下 ,发酵系统呈一定的振荡行为 ,其他四个稀释速率实验组均能够达拟稳态。当稀释速率不超过 0 0 33h^-1 ,流出末级发酵罐的发酵液中酒精浓度可以达到 12 % (V/V)以上 ,残还原糖和残总糖分别在 0 11%和 0 35 % h^-1,流出末级发酵罐的发酵液中酒精浓度可以达到12%（V/V）以上,残还原糖和残总糖分别在0.11%和0.35%（W/V）以下。在稀释速率为0.033h^-1时,计算发酵系统酒精的设备生产强度指标为3.32（g·L^-1·h^-1）,与游离酵母细胞传统酒精发酵工艺相比,增加约1倍。     

几种营养物质对烟草细胞生长和CoQ10含量的影响

研究了蔗糖、KH₂PO₄、NH₄NO₃比对烟草细胞生长和CoQ₁₀量的影响,结果表明,当蔗糖浓度为30g/L时,CoQ₁₀总量最高,此时细胞产量、CoQ₁₀含量和总量分别为19.8g/L、414.7μg/g(dwt)、8212μg/L。在上述蔗糖浓度下,当KH₂PO₄起始浓度为340mg/L、NH₄NO₃为12时,细胞产量、CoQ₁₀含量和总量分别最高,高于此比例时有利于CoQ₁₀形成 ,但不利于细胞生长。     

不同磷、硫及二氧化碳浓度对标志链带藻生长和碳水化合物积累的影响

【目的】为了研究不同磷、硫及二氧化碳浓度对标志链带藻(Desmodesmus insignis)生长与碳水化合物积累的影响,本实验以改良BG11培养基为基础,设计了8种不同初始K_2HPO_4浓度、8种不同初始MgSO_4浓度及4种二氧化碳浓度培养标志链带藻。【方法】采用干重法和苯酚-硫酸法分别测定其生物质浓度与总碳水化合物的含量。【结果】实验结果显示,在高磷浓度(0.460 mmol/L)下生物量达到最高为6.37 g/L,磷浓度为0.230 mmol/L (对照组)时总碳水化合物含量及单位体积产率达到最高,分别为45.40%(%干重)和0.20 g/(L·d)。不同初始MgSO_4浓度实验结果显示,高硫浓度有利于标志链带藻生长及碳水化合物的积累,生物量、总碳水化合物含量及单位体积产率分别在硫浓度为1.217 mmol/L、0.609 mmol/L和1.824 mmol/L时达到最高,分别为7.02 g/L、51.6%(%干重)及0.26 g/(L·d)。当二氧化碳浓度为3%(V/V)时,标志链带藻生物量、总碳水化合物含量及单位体积产率均达到最高,分别为6.81 g/L、44.03%和0.20 g/(L·d)。【结论】因此,磷浓度为0.230 mmol/L、硫浓度为1.824 mmol/L和二氧化碳浓度为3%时最有利于标志链带藻生长及碳水化合物的积累。     

环境因子对小球藻生长的影响及高产油培养条件的优化

探讨了不同环境条件对小球藻(Chlorella sp.)叶绿素荧光动力学参数以及净光合放氧速率的影响,确定了以L₁海水培养基为基础,以8.8 mmol/L浓度的(NH₂)₂CO为氮源、0.145 mmol/L NaH₂PO₄ · H₂O浓度为磷源,在150 μmol · m^-2 · s^-1光照强度、培养温度为18 ℃的小球藻最优培养条件。在此条件下,明显加快了小球藻细胞的生长速度,促进了油脂和脂肪酸的积累,细胞密度增加24%,油脂和脂肪酸含量分别增加了16.8%和66.6%。在培养液中添加外源柠檬酸(最适浓度以0.06 mmol · L^-1 · d^-1为宜)可以明显提高小球藻的生长速度,促进其脂肪酸的积累。同时也可看出,筛选的小球藻藻种具有生长快、易培养、产油高的优点,可作为生物能源研究的良好材料,为海洋微藻的开发利用奠定了基础。     

Cr3+和Cd2+对普通小球藻生长及抗氧化酶活性的影响

[目的] 为探究重金属对淡水绿藻生长的影响。[方法] 选取对水质检测具有明显指示作用的普通小球藻（Chlorella vulgaris）为实验材料,CdCl₂·2H₂O和CrCl₃·7H₂O提供重金属离子,探究不同浓度Cr³⁺和Cd²⁺在单一和复合胁迫下对藻细胞浓度、叶绿素a及相关抗氧化酶活性的影响。[结果] 随着Cr³⁺和Cd²⁺浓度不断增加,藻细胞浓度呈先增长后下降趋势;叶绿素a含量呈现先下降后升高再下降的现象,浓度为1 mg/L的单一和复合胁迫下有最大值,且毒性作用表现为Cr³⁺ < Cd²⁺ < Cr³⁺+Cd²⁺;与藻细胞膜相关的丙二醛（MDA）和过氧化氢（H₂O₂）含量随着重金属离子浓度的增大而增长;重金属离子浓度低于10 mg/L时对藻细胞内抗氧化酶系统中的超氧化物歧化酶（SOD）、过氧化氢酶（CAT）和过氧化物酶（POD）表现为促进作用,而大于10 mg/L时具有抑制作用。[结论] 结果表明在单一或复合重金属胁迫下,普通小球藻会充分调动与抗逆性相关的酶来维持自身的正常生长。     

营养条件和流加发酵对放射型根瘤菌（Rhizobium radiobacter）产辅酶Q10的影响

利用放射型根瘤菌WSH2601（Rhizobium radiobacter WSH2601）重点考察了葡萄糖、蔗糖、玉米浆和蛋白胨、添加物以及流加发酵对细胞生长和产辅酶Q₁₀的影响,结果表明, 葡萄糖和蔗糖适合于生产辅酶Q₁₀的最佳浓度分别为30 g/L和40 g/L;辅酶Q₁₀发酵时玉米浆和蛋白胨的最适浓度分别为11g/L和16g/L;添加蕃茄汁、玉米浆能提高发酵液的生物量,玉米浆、异戊醇、L-甲硫氨基酸等能促进辅酶Q₁₀的积累;与分批发酵相比,在7L罐上流加蔗糖其细胞生物量（DCW）和辅酶Q₁₀积累量增加,若在流加蔗糖的同时流加适当浓度的玉米浆能显著提高辅酶Q₁₀的产量,最大产量达到52.4 mg/L;最大生物量（DCW）和胞内辅酶Q₁₀含量（C/B值）分别达到26.4 g/L和2.38 mg/g-DCW,比不流加的分批发酵分别提高53%和33%,比只流加蔗糖分别提高24%和26%。     

一株高产淀粉绿藻——标志链带藻在废水中的培养及对氮磷的去除

为了研究标志链带藻(Desmodesmus insignis strain JNU24)在不同Na NO3浓度和不同废水浓度培养下的生长与代谢产物积累状况,评估标志链带藻对废水的处理能力,本研究利用柱状光反应器对标志链带藻进行培养,分别对4种Na NO3浓度的BG-11培养基和4种废水浓度培养下藻细胞的生物量、蛋白质含量、碳水化合物含量和淀粉含量进行了测定。结果显示,在BG-11培养基中,氮浓度为9.0 mmol/L时,藻细胞生物质浓度最高,达6.23 g/L;在废水培养下,未稀释的原废水实验组,其藻细胞生物质浓度最高,达10.31 g/L;75%废水培养下,藻细胞的淀粉含量最高(达50.9%),单位体积藻细胞淀粉含量和产率分别为4.86 g/L和405 mg·L~(-1)·d~(-1),且显著高于不同浓度Na NO3的BG-11培养基组。本研究还测定了标志链带藻对废水中氮、磷的去除效率,结果显示不同浓度废水培养下,氮、磷的去除效率最高可达90.8%和98.7%。基于柱状反应器中的最佳培养效果,以9.0 mmol/L Na NO3的BG-11培养基和75%废水于3.0 cm光径平板光生物反应器中进行室内扩大培养,结果显示在75%废水培养下,藻细胞生物质浓度达9.75 g/L,淀粉单位体积含量和产率分别达到4.75 g/L和230 mg·L~(-1)·d~(-1),且为9.0 mmol/L Na NO3的BG-11培养基培养的3倍。通过沉降特性分析发现,藻细胞收获90 min后均完全沉降,具有较强的沉降性能。本研究标志链带藻能够耐受废水中较高的氮、磷浓度,且对废水中氮、磷有显著的去除作用;该藻能利用废水中的营养成分积累较高的生物量和淀粉含量并且藻细胞能快速沉降,具有极高的经济价值和应用价值,是一株淀粉生产能力较高和废水处理能力较强的极具开发潜力的藻株。     

代谢工程强化脱氮副球菌DYTN-1去除氮素污染物

【目的】脱氮副球菌(Paracoccus denitrificans)是一种环境友好的α-变形菌纲菌株,在有氧条件下也可进行反硝化过程,具有较好的脱氮能力。本研究以脱氮副球菌DYTN-1为底盘细胞,筛选氮素诱导型启动子用于强化硝化和反硝化途径,进而达到代谢工程强化脱氮副球菌DYTN-1去除氮素污染物的目的。【方法】通过接合转移的方法分别将过表达amoA、amoB、hao和nirS基因的重组质粒导入脱氮副球菌DYTN-1细胞中。经过荧光定量检测和氮素定量检测对脱氮副球菌DYTN-1的基因元件和氮去除能力进行表征。【结果】从基因组中挖掘了6个受NO₂^‒、NO₃^‒和NH₄⁺诱导的启动子,诱导差异为2‒26倍;且过表达nirS的菌株用2 g/L KNO₃处理24 h后培养基中NO₃^‒的残余量为野生型菌株的67%。同时过表达hao和nirS基因的菌株在用1 g/L NH₄Cl和2 g/L KNO₃处理12 h后,其NO₃^‒的剩余量仅为野生型菌株的50%,且最终总氮的降解效率达79.5%,剩余总氮仅为野生型菌株的一半。【结论】上述研究表明,利用筛选获得的启动子工具在P. denitrificans DYTN-1中进行代谢工程改造强化氮素污染物的去除具有可行性。     

钙离子对鼠角质细胞生长和分化的影响

用无血清培养基培养角质细胞,研究了Ca²⁺对鼠角质细胞生长和分化的影响。实验结果表明,培养基中钙离子最佳浓度为0.2mmol/L。在此浓度下,细胞克隆形成率达到10.8%,细胞的贴壁率达到28.7%,细胞的分化比例和老化比例分别为5.4%和26.3%;当Ca²⁺浓度达到0.6mmol/L以上时,则会引起角质细胞显著的分化和老化。     

不同氮源及其浓度对标志链带藻合成淀粉和油脂的影响北大核心CSCD

【目的】以标志链带藻(Desmodesmus insignis)为实验材料,研究不同氮源及其浓度对该藻生长、总脂和淀粉(碳水化合物)含量的影响,为该藻在生物能源方面的应用提供一定的理论依据。【方法】以硝酸钠、碳酸氢铵或尿素为氮源,5个氮浓度(3、6、9、12和18 mmol/L)的BG-11培养基培养标志链带藻,采用干重法测定生物质浓度、重量法测定总脂、苯酚-硫酸法测定、总碳水化合物和淀粉的含量。【结果】标志链带藻在3种氮源下均能很好的生长。最高油脂含量出现在3 mmol/L硝酸钠实验组,达到32.61%(d.w)。当18 mmol/L碳酸氢铵作为氮源时,总碳水化合物与淀粉的含量以及产率都达到最高,分别为56.54%(d.w)和55.33%(d.w)、0.24和0.23 g/(L·d)。以尿素为氮源时,其生物质浓度和各组分含量与其它氮源实验组差别不大,均有利于该藻的生长及各生化组分含量的积累。【结论】以该藻种生产生物能源的成本等综合考虑,以18 mmol/L碳酸氢铵和尿素为氮源培养标志链带藻最优。     

Effect of plant growth regulators and medium composition on cell growth and saponin production during cell-suspension culture of mountain ginseng (Panax ginseng C. A. mayer)

We have established cell-suspension cultures of mountain ginseng (Panax ginseng G A. Mayer), and have attempted to increase the yield of saponin by manipulating our processing method and culturing factors (e.g., media strengths; the presence of plant growth regulators or sucrose; ratios of NO⁺ ₃/ NH^- ₄). Maximum biomass yield was obtained in media containing 2,4-D. However, saponin productivity was much higher in a medium comprising either IBA or NAA; 7.0 mg/L IBA was optimal for promoting both cell growth (10.0 g/L dry weight) and saponin production (7.29 mg/g DW total ginsenoside). Although the addition of cytokinins (BA and kinetin) did not affect cell growth, the level of saponin (particularly in the Rb group) was enhanced when the media were supplemented with either 0.5 mg/L BA or 0.5 mg/L kinetin. Half- and full-strength MS media were equally suitable for inducing both biomass as well as saponin production. We also investigated the effect of various concentrations of sucrose and nitrogen, and found that 30 g/L sucrose enhanced biomass yield as well as saponin content However, further increases (i.e., up to 70 g/L) led to a decrease in saponin accumulation and biomass production. Maximum growth and saponin productivity were reported from treatments with an initial nitrogen concentration of 30 mM. In general, the amount of saponin increased when the test media had high NO⁺ ₃/ NH^- ₄ ratios; in fact, saponin production was greatest when nitrate was the sole nitrogen source.     

Effects of nitrogen concentration and media replacement on cell growth and lipid production of oleaginous marine microalga Nannochloropsis oceanica DUT01

Cell growth and lipid production of a marine microalga Nannochloropsis oceanica DUT01 were investigated, and fresh medium replacement with different ratios to promote long term cell growth and lipid accumulation was also tested. The highest lipid content reached 64% in nitrogen deplete f/2 medium containing 37.5 mg/L NaNO₃ combined with 1/5 fresh medium replacement, however, the highest lipid titer (0.6 g/L) and lipid productivity (31 mg/L/d) were achieved using BG11 medium containing 1.5 g/L NaNO₃, taking advantage of 1/5 fresh medium replacement as well, which corresponded to the maximum biomass production of 1.4 g/L, highlighting the importance of high biomass accumulation for efficient lipid production. When biomass compositions were monitored throughout the culture, decreased protein content was found to be coupled with increased lipid production, whereas relatively stable carbohydrate content was observed. The fatty acids in the lipid of N. oceanica DUT01 comprise over 65% saturated fatty acids and monounsaturated acids (i.e. palmitic acid (C16:0) and oleic acid (C18:1)), suggesting that N. oceanica DUT01 is a promising candidate for biodiesel production. Interestingly, very high content of hexadecadienoic acid (C16:2, about 26–33%) was produced by DUT01, which distinguished this microalga with other microalgae strains reported so far.     

Effects of nitrogen sources on cell growth and lipid accumulation of green alga <Emphasis Type="Italic">Neochloris oleoabundans</Emphasis>

Microalgal lipids are the oils of future for sustainable biodiesel production. However, relatively high production costs due to low lipid productivity have been one of the major obstacles impeding their commercial production. We studied the effects of nitrogen sources and their concentrations on cell growth and lipid accumulation of Neochloris oleoabundans, one of the most promising oil-rich microalgal species. While the highest lipid cell content of 0.40 g/g was obtained at the lowest sodium nitrate concentration (3 mM), a remarkable lipid productivity of 0.133 g l⁻¹ day⁻¹ was achieved at 5 mM with a lipid cell content of 0.34 g/g and a biomass productivity of 0.40 g l⁻¹ day⁻¹. The highest biomass productivity was obtained at 10 mM sodium nitrate, with a biomass concentration of 3.2 g/l and a biomass productivity of 0.63 g l⁻¹ day⁻¹. It was observed that cell growth continued after the exhaustion of external nitrogen pool, hypothetically supported by the consumption of intracellular nitrogen pools such as chlorophyll molecules. The relationship among nitrate depletion, cell growth, lipid cell content, and cell chlorophyll content are discussed.     

Optimization of lipid production in the oleaginous yeastApiotrichum curvatum in wheypermeate

Summary Lipid production of the oleaginous yeastApiotrichum curvatum was studied in wheypermeate to determine optimum operation conditions in this medium. Studies on the influence of the carbon to nitrogen ratio (C/N-ratio) of the growth medium on lipid production in continuous cultures demonstrated that cellular lipid content in wheypermeate remained constant at 22% of the cell dry weight up to a C/N-ratio of about 25. The maximal dilution rate at which all lactose is consumed in wheypermeate with excess nitrogen was found to be 0.073 h^-1. At C/N-ratios higher than 25–30 lipid content gradually increased to nearly 50% at C/N=70 and the maximal obtainable dilution rate decreased to 0.02 h^-1 at C/N=70. From these studies it could be derived that maximal lipid production rates can be obtained at C/N-ratios of 30–35 in wheypermeate. Since the C/N-ratio of wheypermeate normally has a value between 70 and 101, some additional nitrogen is required to optimize the lipid production rate. Lipid production rates ofA. curvatum in wheypermeate were compared in four different culture modes: batch, fed-batch, continuous and partial recycling cultures. Highest lipid production rates were achieved in culture modes with high cell densities. A lipid production rate of nearly 1 g/l/h was reached in a partial recycling culture. It was calculated that by using this cultivation technique lipid production rates of even 2.9 g/l/h may be reached when the supply of oxygen can be optimized.Nomenclature C/N-ratio carbon to nitrogen ratio of the growth medium (g/g) - C/N_crit C/N-ratio at which there is just enough nitrogen to allow all carbon source to be converted to biomass - D dilution rate=volume of incoming medium per unit time/volume of medium in the culture vessel (h^-1) - D_max maximum dilution rate (h^-1) - DW cell dry weight - L lipid yield (g storage lipid/g carbon source) - specific growth rate (h^-1) - _max maximum specific growth rate (h^-1) - Q_L lipid production rate (g/l/h) - Y_i molecular fraction of carbon substrate that is converted to storage carbohydrate (C-mol/C-mol) - Y_ls maximal amount of storage lipid that can be produced per mol carbon source (C-mol/C-mol)     

Production of γ-linolenic acid by Cunninghamella echinulata cultivated on glucose and orange peel

A newly isolated strain of Cunninghamella echinulata grown on glucose produced significant quantities of biomass and cellular lipids in media with high C/N ratio. The oil yield from glucose consumed increased after nitrogen exhaustion in the growth medium, but gamma-linolenic acid (GLA) content in cellular oil systematically decreased during the lipid accumulation process. When lipid accumulation was completed, GLA concentration in the cellular lipids progressively increased. The highest GLA production (720 mg/l) was achieved in medium with a C/N ratio equal to 163. C. echinulata was also able to grow on orange peel. The C/N ratio in the orange peel decreased from 50 to 26 during solid-state fermentation. Maximum oxygen uptake was observed during assimilation of reducing sugars, whereas a polygalacturonase activity was detected after reducing sugars had been exhausted. The maximum GLA production was 1.2-1.5 mg/g of fermented peel, calculated on a dry weight basis. After enrichment of the pulp with inorganic nitrogen and glucose, an increase in the production of oil and GLA was observed.     

利用平板反应器大量培养高产油绿藻——尖状栅藻的生长和油脂积累规律

以新近分离的淡水绿藻--尖状栅藻(Scenedesmus acuminatus)为研究对象,将改良的BG-11培养基中的初始NaNO₃浓度降低为6.0mmol/L和3.6mmol/L,利用新设计的内置拉筋平板式光生物反应器对尖状栅藻(S. acuminatus)进行大量培养。测定不同时相的生物量、总脂含量、脂组分含量及脂肪酸组成和含量,分析尖状栅藻(S. acuminatus)大量培养时的生长和油脂积累规律。当初始NaNO₃浓度为6mmol/L时其最高生物量(6.27g/L)明显高于初始NaNO₃浓度为3.6mmol/L时的生物量(5.30g/L);而最高的总脂含量在初始NaNO₃浓度为3.6mmol/L时获得为干重的56.6%,高于初始NaNO₃浓度为6mmol/L时的总脂含量(51.6%)。总脂经硅胶柱层析分级后得到三种类型的脂组分:中性脂、糖脂和磷脂,随着培养时间的延长中性脂含量逐渐增加,培养至18d后,中性脂的含量分别达到总脂的 90.9%(6 mmol/L NaNO₃)和 92.0%(3.6 mmol/L NaNO₃)及干重的 47.5%(6.0 mmol/L NaNO₃)和 51.4%(3.6 mmol/L NaNO₃)。主要脂肪酸组成为棕榈酸、棕榈油酸、硬脂酸、油酸、亚麻油酸和亚麻酸,这六种脂肪酸在不同时相的含量变化范围分别为89.92%~96.18%(占总脂肪酸)和12.5%~50.7%(占细胞干重)。总脂、中性脂及总脂肪酸单位体积产率分别为:0.18 g/L/d,0.16 g/L/d和0.15 g/L/d(6.0 mmol/L NaNO₃)及0.16 g/L/d,0.15 g/L/d和0.15 g/L/d(3.6 mmol/L NaNO₃)。研究结果表明,尖状栅藻(S. acuminatus)是一株易于规模化培养、脂肪酸组成适合于生物柴油生产的高产油微藻。     

硫素营养水平对产油尖状栅藻光合生理及生化组成的影响

以产油尖状栅藻(Scenedesmus acuminatus)为实验材料, 在持续300 μmol photons/(m2·s)光照条件下, 选用3种不同初始Na₂SO₄浓度(2.0S、1.0S对照、0.25S)的改良BG-11培养基, 在Φ3.0 cm×60 cm光生物反应器中进行通气培养, 研究分析硫素营养水平与尖状栅藻产油过程光合生理和生化组成的关系。实验结果表明, 初始硫素浓度对尖状栅藻生长有显著的影响(P<0.05), Na₂SO₄初始浓度为2.0S实验组的生物量最高, 为7.47 g/L, 显著高于1.0S组(6.43 g/L)和0.25S组(4.17 g/L)(P<0.05), 说明加富硫素营养可促进藻细胞的生长。尖状栅藻细胞的叶绿素a、b以及总类胡萝卜素含量变化均与培养基中初始硫素营养水平呈正相关。在培养初期低硫营养有利于藻细胞快速积累碳水化合物, 0.25S实验组碳水化合物含量最高, 占干重的44.37%, 比1.0S和2.0S组分别高出14.43%和13.78%, 培养后期总碳水化合物和蛋白含量均发生不同程度的降低, 转向大量累积油脂, 0.25S实验组的总脂含量最高, 达55.15% DW, 显著高于1.0S和2.0S组(P<0.05)。藻细胞的光合放氧速率、PSⅡ最大光能转化效率(F_v/F_m)、实际光能转换效率(Yield)以及相对电子传递效率(ETR)均与培养液的初始硫素浓度呈正相关, 在整个培养周期中呈先上升后下降的趋势。77 K低温荧光显示, 尖状栅藻在培养初期2个光系统之间存在光能调配现象。上述结果说明, 尖状栅藻细胞的生长、油脂积累和光合生理状况与硫素营养水平直接相关。     

光强及氮浓度对丝状绿藻双星藻生长及生化组成的影响

[背景]环境因子和营养因子对微藻的生长和生化组成都有显著的影响,其中光强和氮浓度是最重要的两个条件。[目的]研究不同光强和初始氮浓度对丝状绿藻-双星藻(Zygnema sp.)生长及生化组成的影响。[方法]采用改良的BBM培养基,设置了两组光强[100μmol/(m^2·s)和300μmol/(m^2·s)]和6种初始氮浓度(3、6、9、12、15和18 mmol/L)在柱状光生物反应器中对双星藻进行培养。[结果]在高光强条件下[300μmol/(m^2·s)],12 mmol/L初始氮浓度最有利于双星藻生物质的积累,其最高生物量可以达到6.60 g/L,而初始低氮浓度(3 mmol/L)则促进了油脂和脂肪酸的积累,油脂最高含量占干重的32.13%,且脂肪酸组成主要包括棕榈酸(C16:0)、油酸(C18:1)、亚油酸(C18:2)和亚麻酸(C18:3),其中油酸含量最高达到总脂肪酸含量的55.01%;在低光强条件下[100μmol/(m^2·s)],初始氮浓度为18 mmol/L时,总蛋白质和总碳水化合物的含量达到最高,分别占干重的16.35%和37.70%,而总脂含量仅占干重10.16%。[结论]光强和初始氮浓度对双星藻生长具有较大影响,通过调节光强和初始氮浓度可有效提高双星藻目标代谢产物的积累。