Mayo W P, Elrifi I R, Turpin D H
Department of Biology, Queen's University, Kingston, Ontario, Canada K7L 3N6.
Plant Physiol. 1989 Jun;90(2):720-7. doi: 10.1104/pp.90.2.720.
To examine the factors which limit photosynthesis and their role in photosynthetic adaptation to growth at low dissolved inorganic carbon (DIC), Synechococcus leopoliensis was grown at three concentrations (as signified by brackets) of DIC, high (1000-1800 micromolar), intermediate (200-300 micromolar), and low (10-20 micromolar). In all cell types photosynthesis varied from being ribulose bisphosphate (RuBP)-saturated at low external [DIC] to RuBP-limited at high external [DIC]. The maximum rate of photosynthesis (P(max)) was achieved when the internal concentration of RuBP fell below the active site density of RuBP carboxylase/oxygenase (Rubisco). At rates of photosynthesis below P(max), photosynthetic capacity was limited by the ability of the cell to transport inorganic carbon and to supply CO(2) to Rubisco. Adaptation to low DIC was reflected by a decrease in the [DIC] required to half-saturate photosynthesis. Simultaneous mass-spectrometric measurement of rates of photosynthesis and DIC transport showed that the initial slope of the photosynthesis versus [DIC] curve is identical to the initial slope of the DIC transport versus [DIC] curve. This provided evidence that the enhanced capacity for DIC transport which occurs upon adaptation to low [DIC] was responsible for the increase in the initial slope of the photosynthesis versus [DIC] curve and therefore the decrease in the half saturation constant of photosynthesis with respect to DIC. Levels of RuBP and in vitro Rubisco activity varied only slightly between high and intermediate [DIC] grown cells but fell significantly (65-70%) in low [DIC] grown cells. Maximum rates of photosynthesis followed a similar pattern with P(max) only slightly lower in intermediate [DIC] grown cells than in high [DIC] grown cells, but much lower in low [DIC] grown cells. The changing response of photosynthesis to [DIC] during adaptation to low DIC, may be explained by the interaction between DIC-transport limited and [RuBP]-limited photosynthesis.
为了研究限制光合作用的因素及其在光合适应低溶解无机碳(DIC)生长中的作用,将利奥波利斯聚球藻在三种DIC浓度(括号内表示)下培养,高浓度(1000 - 1800微摩尔)、中等浓度(200 - 300微摩尔)和低浓度(10 - 20微摩尔)。在所有细胞类型中,光合作用在低外部[DIC]时从被核酮糖二磷酸(RuBP)饱和转变为在高外部[DIC]时受RuBP限制。当RuBP的内部浓度低于RuBP羧化酶/加氧酶(Rubisco)的活性位点密度时,达到最大光合速率(P(max))。在低于P(max)的光合速率下,光合能力受细胞运输无机碳并向Rubisco供应CO₂的能力限制。对低DIC的适应表现为使光合作用半饱和所需的[DIC]降低。同时通过质谱法测量光合速率和DIC运输速率表明,光合作用与[DIC]曲线的初始斜率与DIC运输与[DIC]曲线的初始斜率相同。这提供了证据,表明适应低[DIC]时发生的DIC运输能力增强是光合作用与[DIC]曲线初始斜率增加以及因此光合作用相对于DIC的半饱和常数降低的原因。在高[DIC]和中等[DIC]培养的细胞之间,RuBP水平和体外Rubisco活性仅略有变化,但在低[DIC]培养的细胞中显著下降(65 - 70%)。最大光合速率遵循类似模式,中等[DIC]培养的细胞中的P(max)仅略低于高[DIC]培养的细胞,但在低[DIC]培养的细胞中要低得多。在适应低DIC过程中光合作用对[DIC]的变化响应,可能由DIC运输限制的光合作用和[RuBP]限制的光合作用之间的相互作用来解释。