葡萄糖对小球藻(Chloralla sp. HN08)光合作用和生长的影响

【目的】探讨葡萄糖作为外加碳源对热带海洋小球藻(Chloralla sp.HN08)生物质生产和脂、光合色素、碳水化合物及可溶性蛋白等细胞主要成份含量的影响。【方法】分析比较小球藻HN08在光合自养和兼养(添加10 g/L葡萄糖)2种营养方式下的生长速率、细胞密度、光合放氧速率、油脂相对含量,以及可溶性总糖、淀粉和可溶性蛋白的含量。【结果】结果表明,在光照条件下葡萄糖(10 g/L)能促进小球藻(Chloralla sp.HN08)生长,提高细胞终密度,而异养条件下藻细胞逐渐衰亡。兼养条件下,细胞相对生长速率及细胞终密度分别是自养条件下的6.8倍和1.3倍。兼养藻细胞中可溶性糖、淀粉、油脂含量显著高于(P0.05)光合自养细胞,然而可溶性蛋白质和光合色素含量显著低于(P0.05)光合自养细胞。添加葡萄糖的小球藻液的光饱和点和呼吸速率均高于光自养条件下的细胞,但2种培养条件下藻液的净光合速率无显著差异(P0.05)。【结论】光照条件下,添加葡萄糖可显著提高小球藻HN08相对生长速率和细胞终密度,促进油脂与淀粉的积累。     

小球藻两个品系在自养与异养条件下的生长、能荷与色素差异

Chlorella protothecoides中国品系(C品系)与美国品系(A品系)在自养培养基中生长正常。在高浓度葡萄糖、低浓度有机氮的异养生长条件下,C品系仍为绿色,细胞生长与繁殖缓慢,指数期生长速率降低,细胞内腺苷酸能荷值(AEC)下降,但细胞仍保留叶绿素;A品系细胞转变成乳黄色,细胞生长与繁殖加快,指数期生长速率是自养细胞的2倍,细胞内腺苷酸能荷值仍保持高水平,向异养条件转换后约24h,细胞内叶绿素基本消失,重新向自养条件转换后细胞内叶绿素又逐渐恢复。AEC值是判别微藻在异养条件下能量代谢与生理状态的良好指标。同一种小球藻不同品系间的上述差异可能与细胞内基因调控的差异相关联。     

PP333用于藻类培养影响异养小球藻的生长及蛋白质含量

用植物生长物质PS333处理异养小球藻,研究了PP333对异养小球藻的生长及蛋白质含量的影响,实验结果表明,PP333能抑制异养小球藻的生长,同时也能显著提高小球藻的蛋白质含量,选取适当浓度的PP333处理异养小球藻可达到小球藻的细胞密度较高,其蛋白质含量又接近自养水平的目的。用50mg/L PP333处理异养小球藻,摇瓶批次培养时,小球藻的蛋白质含量与生物量分别为47.88%和3.60g/L,而对照的分别为37.34%和4.21g/L,摇瓶分批流加培养时,小球藻的蛋白质含量与生物量分别为50.96%和6.97g/L,而对照的分别为38.56%和10.99g/L,蛋白质量促进率和生物量抑制率摇瓶批次培养时分别为28.2%和14.5%,摇瓶分批流加培养时分别达32.2%和36.6%。     

自养和兼养条件下蛋白核小球藻昼夜节律的响应

【目的】研究自养和兼养两种培养方式对蛋白核小球藻(Chlorella pyrenoidosa)生长、细胞分裂和生化组分积累的影响,探讨人工培养蛋白核小球藻的昼夜节律响应机制和优化技术。【方法】小球藻自养培养采用BG11培养基,兼养培养基在BG11培养基中添加4种不同浓度(1、5、10、20 g/L)的葡萄糖,培养周期为10 d。血球板计数法测定藻细胞浓度,干重法测定藻细胞生物量。显微观察藻细胞大小和分裂情况。脂染色法测定小球藻总脂的含量,藻细胞的叶绿素、蛋白和淀粉分别采用甲醇、氢氧化钠、硝酸钙浸提后通过紫外分光光度法定量测定。【结果】葡萄糖兼养培养对蛋白核小球藻具有显著的促生长效应,最适浓度为10 g/L。10 d收获时,兼养组(10 g/L葡萄糖)藻细胞浓度和干重分别是自养组的2.57倍和6.73倍。分析一昼夜中的藻细胞增殖规律可知,第2天和第5天时自养组中增殖的新生子细胞约有76.00%在黑暗期分裂产生,而兼养组中第2天和第5天光照期的新细胞增殖量占比分别达到40.90%和67.50%。一昼夜内藻细胞大小的迁移动态监测表明,第2天自养组藻细胞的体积变化静息期为8 h,兼养组只有4 h;第5天两组藻细胞大小迁移动态的昼夜节律明显,但兼养组黑暗结束后较大细胞(D6μm)占比显著高于自养组。第8天时,兼养组藻细胞已处于稳定期,总脂和蛋白含量均显著高于自养组,藻细胞总脂和色素含量在一昼夜中相对稳定,但蛋白和淀粉含量分别在光照8 h和12 h左右达到峰值。从第2天开始,对兼养组细胞每天进行2 h光延长,收获时藻细胞浓度和干重分别比对照组提高13%和11%。【结论】葡萄糖兼养培养能大幅提高蛋白核小球藻的生物量。蛋白核小球藻生长增殖与生化组分积累均受昼夜节律调控,自养条件下藻细胞以光照期生长黑暗期增殖为主。兼养培养提高藻细胞生物量的机制在于缩短藻细胞生长静息期,在昼夜节律中加速藻细胞生长并显著提高通过细胞周期检查点的细胞比例,光照期效应尤其明显。藻细胞蛋白和淀粉含量昼夜节律明显,最佳收获时间分别在光照8 h和12 h后。     

有机碳化合物对鱼腥藻7120生长的影响

在培养基中添加多种有机碳化合物对鱼腥藻7120进行培养。结果表明,葡萄糖的存在能明显地促进细胞的生长,但细胞仅能有限地利用葡萄糖;细胞混合营养生长的饱和光强约为80μEm^-2s^-1。乙酸、蔗糖、乙醇和甘油对细胞生长的影响不很显著,乳酸、柠檬酸、谷氨酸和甘氨酸表现出明显的抑制作用。鱼腥藻7120不能利用葡萄糖进行化能异养生长和光激活的化能异养生长,但有轻微的光异养现象。     

不同营养方式对普通小球藻生长代谢及生化组分的影响

摘要:【目的】系统研究自养、混养和异养3种营养方式对真核模式微藻———普通小球藻(Chlorella vulgaris)生长特性、细胞生化组分和碳代谢途径关键酶活性的影响。【方法】以C．vulgaris为研究对象,通过设置光合自养、混养和异养3 种营养方式,采用光谱学、色谱学方法,研究不同营养方式对C．vulgaris从生长特性、细胞组分合成和碳代谢等方面的影响。【结果】C．vulgaris依次经自养至混养和异养的培养方式转变中,藻细胞的可溶性糖和油脂含量显著提高,油脂中C16、C18不饱和脂肪酸的相对含量降低,而饱和脂肪酸的含量升高;蛋白质含量、光合色素含量显著下降,18种氨基酸的相对含量也呈下降趋势;葡萄糖的添加可抑制藻细胞吸收和积累除碳元素以外的其他测试元素。在添加葡萄糖的前提下,光照可促进藻细胞的生长量、不饱和脂肪酸和氨基酸,以及除碳元素以外的其他测试参数增加。对微藻胞外碳酸酐酶和核酮糖-1,5-二磷酸 羧化酶的活性分析结果表明,异养和混养直接影响C．vulgaris的碳代谢途径。【结论】光源和葡萄糖的供给与否直接影响C．vulgaris的生长代谢和生化组分合成,葡萄糖的添加在显著促进藻细胞生物量积累的同时,刺激碳素(糖类和油脂)生化成分的合成,而抑制氮素成分(蛋白质和光合色素)的合成;在光照条件下培养基质中葡萄糖的浓度和消耗水平直接决定藻细胞主营自养或异养生长。添加有机碳源葡萄糖的混养(光照)和异养(暗处理)培养可促进藻细胞的生长,异养和自养的生物量之和接近于混养,表明混养是最佳的藻细胞营养生长方式。     

以异养细胞作为种子的椭圆小球藻产油脂光自养培养优化

异养细胞种子/光自养培养方法是一种可异养培养的能源微藻培养的有效方法,但已有文献尚未从工艺优化角度考察其发展潜力。为了获得较高细胞密度的用于光自养培养的种子和提高光自养培养的细胞密度与油脂产率,对异养细胞种子/光自养培养的培养基和培养条件进行了优化。结果表明,采用优化后的培养基,椭圆小球藻在摇瓶中异养培养的最高藻细胞密度可达11.04 g/L,比在初始培养基条件下提高了28.0%,在5 L发酵罐中异养培养的藻细胞密度达到73.89 g/L;在2 L柱式光生物反应器中光自养培养的藻细胞密度、油脂含量和油脂产率分别达1.62 g/L、36.34%和6.1 mg/(L·h),油脂成分主要为含C16-C18碳链的脂肪酸,是制备生物柴油的理想原料。经过优化,异养细胞种子/光自养培养这一方法能够显著地提高椭圆小球藻产油脂的能力,这进一步表明异养细胞种子/光自养培养方法有望成为可异养的能源微藻的高效培养方式。     

厌氧条件下小球藻细胞的异养转化和乳酸发酵(简报)

某些藻类植物,如小球藻——一种单细胞绿藻,不但能利用无机碳源通过光合作用进行自养生长,还能利用有机碳源转化为异养生长,这种转化又是可逆的。迄今为止,对于人工控制下藻细胞向异养转化的代谢和调控机理尚不清楚。本文通过分析小球藻细胞异养转化过程对氧气的依赖性,进一步研究它们在厌氧条件下的生长和乳酸发酵特征,探讨可异养转化的单细胞藻类(作为特殊的实验生物系统)在发酵工程和细胞工程领域里应用的可能性。     

热带普通小球藻培养模式的筛选及其培养基的优化

【背景】从海南热带海区中分离得到一株微藻,其生长速度快、适应力强,经鉴定该微藻为普通小球藻。【目的】提高热带普通小球藻的生长速率。【方法】以"宁波大学3#微藻培养液配方"为基础培养液,分别添加有机碳(C6H12O6和CH3COONa)对热带普通小球藻进行自养、兼养及异养培养,获得促进热带普通小球藻快速生长的培养方式。在"宁波大学3#微藻培养液配方"的基础上对热带普通小球藻的兼养培养基配方进行优化,并用优化兼养培养基与"宁波大学3#微藻培养基"对比培养热带普通小球藻。【结果】添加6 g/L CH3COONa的兼养模式促进热带普通小球藻生长效果最好;优化的兼养培养基配方为:6 g/L CH3COONa,20 mg/L(NH4)2SO4-N,5 mg/L Na H2PO4-P,3 mg/L Fe SO4-Fe,1 mg/L Vitamin B1和0.000 5 mg/L Vitamin B12。对比培养实验结果显示,培养第6天,兼养培养液收获的生物量(细胞密度)达4.20×107 cells/m L,是"宁波大学3#配方微藻培养液"的2.30倍。【结论】兼养培养模式为热带普通小球藻的最佳培养模式,优化的兼养培养基极显著地提高了热带普通小球藻的生物量(P0.01)。     

有机碳源对三角褐指藻生长、胞内物质和脂肪酸组分的影响

研究了3种有机碳对三角褐指藻生长、胞内物质和脂肪酸组分的影响。结果表明, 三角褐指藻具有利用有机碳进行兼养生长的能力, 生长速率加快, 倍增时间缩短, 生物量显著提高, 100 mmol/L甘油兼养的生物量最高(713 mg/L), 是自养(460 mg/L)的1.60倍, 乙酸钠和葡萄糖兼养的生物量分别是自养的1.28倍和1.21倍。兼养下蛋白质含量较自养明显下降, 碳水化合物和总脂含量高于自养, 乙酸钠和甘油兼养的总脂含量分别是自养的1.43倍和1.20倍, 葡萄糖兼养的总脂含量与自养无明显差异。3种有机碳兼养的饱和脂肪酸和单不饱和脂肪酸占总脂肪酸的比例增大, 多不饱和脂肪酸比例降低, EPA(eicosapentaenoic acid)比例降低, 乙酸钠兼养的胞内EPA含量(6.23%)和产量(36.59 mg/L)均高于自养, 分别是自养的1.10倍和1.40倍, 甘油和葡萄糖兼养的EPA含量和产量均低于自养。     

温度、盐度和pH对小球藻生长率的联合效应

采用中心复合设计（CCD）研究了温度（1634℃）、盐度（1545）和pH（6.09.0）对小球藻（Chlorella sp. CHX-1）生长的联合效应。结果表明,温度、盐度与pH的一次、二次效应都对小球藻比生长速率有极显著影响（P0.01）;温度与盐度间、温度与pH间的互作效应对小球藻比生长速率影响显著（P0.05）,而盐度与pH间的互作效应影响不显著（P0.05）;三因子影响度大小依次为:温度pH盐度。采用响应曲面法建立了温度、盐度和pH对小球藻比生长速率影响的模型方程,该模型的决定系数0.9759,矫正决定系数0.9542,说明模型的拟合度极高;模型的预测决定系数0.8367,表明可用于预测小球藻比生长速率的变化。通过模型优化和验证试验,得出在温度、盐度和pH组合为26.7℃/25.5/7.3时,小球藻比生长速率达到最大值0.69,满意度为0.999。本试验结果可为小球藻生产提供理论指导。       

ISOLATION AND CHARACTERIZATION OF CHLORELLA SOROKINIANA GXNN01 (CHLOROPHYTA) WITH THE PROPERTIES OF HETEROTROPHIC AND MICROAEROBIC GROWTH1

Heterotrophic and anaerobic microalgae are of significance in both basic research and industrial application. A microalga strain was isolated from a wastewater treatment pond and identified as Chlorella sorokiniana Shihira et W. R. Krauss GXNN01 in terms of morphology, physiology, and phylogeny. The strain grows rapidly in heterotrophic or mixotrophic conditions with addition of various carbon sources, and even in anaerobic conditions. The maximum growth rate reached 0.28 d^?1 when using d,l ‐malate as the carbon source, and the protein content of the microalgae was 75.32% in cell dry weight. The strain was shown to be capable of (1) utilizing d,l ‐malate only with light, (2) inhibiting photosynthesis in mixotrophic growth, and (3) growing in anaerobic conditions with regular photosynthesis and producing oxygen internally. This study demonstrates the influence of oxygen (aerobic vs. anaerobic) and metabolic regime (autotrophy, mixotrophy, heterotrophy) on the physiological state of the cell.     

鱼腥藻1017株的混合营养型生长

鱼腥藻１０１７株混合营养型生长有其特点,外源葡萄糖对生长的刺激不仅在低光强（８００ｌｘ）,而且在高光强（７０００ｌｘ）也表现出来。其混合营养型生长速率在８００－７０００ｌｘ范围内随光照强度的增加而增加,在葡萄糖浓度５－２０ｍｍｏｌ／Ｌ范围内随外源葡萄糖浓度增加而增加。鱼腥藻１０１７株混合营养型生长与光能自养生长相比,生长速率明显提高,对数生长期延长,收获物浓度显著增高,生物量显著提高。     

GRAZING AND GROWTH OF THE MIXOTROPHIC CHRYSOMONAD POTERIOOCHROMONAS MALHAMENSIS (CHRYSOPHYCEAE) FEEDING ON ALGAE

The growth and grazing characteristics of Poterioochromonas malhamensis (Pringsheim) Peterfi (= Ochromonas malhamensis Pringsheim) (ca. 8 μm) feeding on phytoplankton, including the cyanobacteria Synechococcus sp. (ca. 2 μm) and Microcystis viridis (A. Brown) Lemmermann (ca. 6 μm) and the green alga Chlorella pyrenoidosa Chick (ca. 13 μm), were investigated in laboratory experiments involving the following treatments: (1) light without added algal prey (autotrophy), (2) light with added algal prey (mixotrophy), and (3) dark with added algal prey (phagotrophy). There were significantly higher cell numbers under mixotrophic and phagotrophic growth than under autotrophic growth. With phytoplankton as food, growth rates under both mixotrophy and phagotrophy were about two or three times higher than those under autotrophy, indicating that the algal diets were readily able to support the population growth of P. malhamensis. There were no significant differences in growth rate between mixotrophic and phagotrophic cultures during exponential growth. The ingestion rate of P. malhamensis with algal prey was also similar under both continuous light and dark. Poterioochromonas malhamensis ingested on average 0.27 M. viridis cells·flagellate^{− 1} ·h^{− 1} and 0.18 C. pyrenoidosa cells·flagellate^{− 1} ·h^{− 1} in continuous light and 0.25 M. viridis cells·flagellate^{− 1} ·h^{− 1} and 0.18 C. pyrenoidosa cells·flagellate^{− 1} ·h^{− 1} in continuous dark during exponential growth. The results showed that light had no effect on the growth and ingestion rates of P. malhamensis for phagotrophy during exponential growth. However, phagotrophic populations of P. malhamensis were incapable of growth in continuous darkness for longer than 5 days. Populations of P. malhamensis showed no increase when prey was added again after 4 days in continuous darkness, indicating that light is necessary for sustained phagotrophic growth of P. malhamensis. The study suggests that P. malhamensis, which has strong tolerance for light, is light dependent for phagotrophy.     

MIXOTROPHIC ALGAE CONSTRAIN THE LOSS OF ORGANIC CARBON BY EXUDATION1

Algae of various taxonomic groups are capable of assimilating dissolved organic carbon (DOC) from their environments (mixotrophy). Recently, we reported that, with increasing biomass of mixotrophs, heterotrophic bacteria did not increase. We hypothesized that algal uptake of external DOC may outweigh their release of DOC by exudation (H1). Here, we addressed an alternative hypothesis that algae did not assimilate external DOC but constrained the release of DOC (H2). In chemostat experiments, we cultured the mixotrophic Chlamydomonas acidophila Negoro together with heterotrophic bacteria. As external substrates, we used glucose, which was potentially available for both bacteria and algae, or fructose, which was available only for bacteria. We increased the biomass of algae by the stepwise addition of phosphorus. Bacterial biomass did not increase in experiments using glucose or when fructose was offered, suggesting that mechanisms other than algal mixotrophy (H1) kept concentrations of bacteria low. Measured exudation rates (percent extracellular release, PER) of mixotrophic algae (Cd. acidophila, Chlorella protothecoides W. Krüger) were very low and ranged between 1.0% and 3.5% at low and moderately high phosphorus concentrations. In contrast, an obligately phototrophic alga (Chlamydomonas segnis H. Ettl) showed higher exudation rates, particularly under phosphorus limitation (70%). The results support H2. If mixotrophy is considered as a mechanism to recycle organic exudates from near the cell surface, this would explain why algae retained mixotrophic capabilities although they cannot compete with bacteria for external organic carbon.     

The effect of mixotrophy on microalgal growth, lipid content, and expression levels of three pathway genes in Chlorella sorokiniana

Nannochloropsis oculata CCMP 525, Dunaliella salina FACHB 435, and Chlorella sorokiniana CCTCC M209220 were compared in mixotrophic and photoautotrophic cultures in terms of growth rate, protein, and lipid content. Growth improved in glucose, and the biomass productivities of N. oculata, D. salina, and C. sorokiniana were found to be 1.4-, 2.2- and 4.2-fold that observed photoautotrophically. However, biomass and lipid production decreased at the highest glucose concentrations. Meanwhile, the content of protein and lipid were significantly augmented for mixotrophic conditions at least for some species. C. sorokiniana was found to be well suited for lipid production based on its high biomass production rate and lipid content reaching 51% during mixotrophy. Expression levels of accD (heteromeric acetyl-CoA carboxylase beta subunit), acc1 (homomeric acetyl-CoA carboxylase), rbcL (ribulose 1, 5-bisphosphate carboxylase/oxygenase large subunit) genes in C. sorokiniana were studied by real-time PCR. Increased expression levels of accD reflect the increased lipid content in stationary phase of mixotrophic growth, but expression of the acc1 gene remains low, suggesting that this gene may not be critical to lipid accumulation. Additionally, reduction of expression of the rbcL gene during mixotrophy indicated that utilization of glucose was found to reduce the role of this gene and photosynthesis.     

Growth characteristics and eicosapentaenoic acid production by Nannochloropsis sp. in mixotrophic conditions

Nannochloropsis sp. was grown under mixotrophic conditions with 30 mM glucose as carbon source, reaching 507 mg dry wt l(-1) after 8 d. This was 1.4-fold of that obtained under photoautotrophic conditions. Under mixotrophic and photoautotrophic cultivations, the net photosynthetic rate of Nannochloropsis sp. did not change but the respiratory rate increased in the mixotrophic cultivation. The yield of eicosapentaenoic acid was 22 mg l(-1) in the mixotrophic cultivation and 20 mg l(-1) under the photoautotrophic cultivation.     

环境因子对金藻生长和噬藻速率的影响

在微囊藻的大量培养过程中分离到一株能够快速吞噬微囊藻的鞭毛虫-金藻Poterioochromonas sp.,其具有混和营养的特点。研究以人工培养的铜绿微囊藻(Microcystis aeruginosa FACHB469)为饵料,研究了起始饵料浓度、光强、温度和pH等环境因子对Poterioochromonas sp.生长和吞噬饵料速率的影响。结果显示:当无饵料时,金藻的自养生长与光强和温度相关,而与pH无相关性。喂食饵料能显著促进金藻的生长,其吞噬速率和生长速率与起始饵料浓度相关性强,可分别用Michaelis-Menten方程和Monod方程拟合。提供相同量的饵料时,金藻的生长与光强相关性显著,而与温度和pH的相关性不显著;其吞噬速率与pH呈现负相关关系,而与光强和温度相关性不显著。除了在不同pH下的生长外,混合营养时金藻的生长速率与吞噬速率之间存在显著的正相关关系。实验表明适于Poterioochromonas sp.生存并吞噬微囊藻的环境条件较广,这也是进一步探索利用Poterioochromonas sp.控制微囊藻水华的前提。       

EFFICIENCY OF GROWTH AND NUTRIENT UPTAKE FROM WASTEWATER BY HETEROTROPHIC,AUTOTROPHIC, AND MIXOTROPHIC CULTIVATION OF CHLORELLA VULGARIS IMMOBILIZED WITH AZOSPIRILLUM BRASILENSE1

Heterotrophic growth of microalgae presents significant economic advantages over the more common autotrophic cultivation. The efficiency of growth and nitrogen, phosphorus, and glucose uptake from synthetic wastewater was compared under heterotrophic, autotrophic, and mixotrophic regimes of Chlorella vulgaris Beij. immobilized in alginate beads, either alone or with the bacterium Azospirillum brasilense. Heterotrophic cultivation of C. vulgaris growing alone was superior to autotrophic cultivation. The added bacteria enhanced growth only under autotrophic and mixotrophic cultivations. Uptake of ammonium by the culture, yield of cells per ammonium unit, and total volumetric productivity of the culture were the highest under heterotrophic conditions when the microalga grew without the bacterium. Uptake of phosphate was higher under autotrophic conditions and similar under the other two regimes. Positive influence of the addition of A. brasilense was found only when light was supplied (autotrophic and mixotrophic), where affinity to phosphate and yield per phosphate unit were the highest under heterotrophic conditions. The pH of the culture was significantly reduced in all regimes where glucose was consumed, similarly in heterotrophic and mixotrophic cultures. It was concluded that the heterotrophic regime, using glucose, is superior to autotrophic and mixotrophic regimes for the uptake of ammonium and phosphate. Addition of A. brasilense positively affects the nutrient uptake only in the two regimes supplied with light.     

pH对小球藻Chlorella sp. XQ-200419光合作用、生长和产油的影响

以一种生长快、油脂含量高的小球藻(Chlorella sp. XQ-200419)为实验材料, 利用测定净光合放氧速率的方法研究了pH对其光合作用的影响; 使用改良的BG-11培养基在微藻环形培养池模拟系统中进行分批培养, 培养周期为8d, 培养过程中使用 pH控制仪在线监测藻液的pH, 根据pH变化, 自动接通、关闭CO2通气管道, 将藻液pH分别控制在5.06.0, 7.08.0, 8.09.0, 9.010.0, 10.011.0内, 研究pH对生长速率、生物质面积产率、总脂含量和总脂面积产率的影响。主要结果如下: 藻液pH对小球藻Chlorella sp. XQ-200419光合放氧、生长速率、生物质产率、总脂含量和产率都有显著影响, 适宜的pH范围是7.09.0, 在此范围内, 光合放氧、生长速率、生物质产率、总脂含量和产率均保持较高水平, 且pH的影响不显著; pH低于7.0, 高于9.0, 其光合放氧、生长速率、生物质产率、总脂含量和产率都显著降低。这表明pH对小球藻Chlorella sp. XQ-200419光合作用的影响和对生长、产油的影响是一致的。pH 7.08.0, 小球藻的生物质平均面积产率和总脂平均面积产率都达到最大值, 分别是8.9 g/(m2d)和2269.5 mg/(m2d); 当藻液pH超过10.0, 生物质平均面积产率和总脂平均面积产率分别降低42.1%和60.0%。适合于小球藻生长的pH也有利于其积累油脂, 所以, pH对小球藻产油的影响是一种适宜模式, 而非胁迫模式。规模化培养小球藻Chlorella sp. XQ-200419, 通过补充CO2将藻液pH控制在7.09.0内, 可以获得高生物质产率和总脂产率。研究结果反映出pH对小球藻光合作用、生长和产油影响的规律, 也为规模化培养小球藻生产微藻油脂过程中合理控制藻液pH提供了依据。