三角褐指藻dxs基因克隆与诱导表达

为研究6种外源因素处理对三角褐指藻(Phaeodactylum tricornutum)1-脱氧-D-木酮糖-5-磷酸合成酶(DXS)基因表达的影响, 通过高通量转录组测序技术获得三角褐指藻dxs基因cDNA全长序列, 并对其进行生物信息学分析。研究结果表明, 三角褐指藻dxs基因cDNA全长2476 bp, ORF全长2193 bp, 编码730个氨基酸, 具有高度保守的ThDP结合位点和转酮醇酶结构域。三角褐指藻DXS蛋白为亲水性稳定蛋白, 相对分子质量(M_w)为79.31 kD, 理论等电点为6.65, 具有信号肽、跨膜区域、卷曲螺旋和TM-螺旋等。系统进化树分析结果表明, DXS蛋白进化树分为高等植物和藻类2个分支, 高等植物DXS蛋白进一步分为DXS1和DXS2两支, 藻类DXS蛋白聚类为3个分支, 分别为硅藻门、红藻门和绿藻门分支, 三角褐指藻聚类在硅藻门分支上。诱导表达调控结果表明, 三角褐指藻dxs基因受到茉莉酸甲酯(MeJA)、花生四烯酸(AA)、硫酸铈铵(ACS)、光合诱导素(PIF)、光合抑制剂(DCMU)和光质等6种外源因素的诱导调控。在100 μmol/L MeJA、62.5 mg/L AA、1.6 mg/L ACS、1.00 μg/L PIF、0.2 mg/L DCMU和紫光处理下, 三角褐指藻dxs基因表达量最高。在MeJA和光质处理下, 三角褐指藻dxs基因表达量与岩藻黄素含量变化趋势一致, 说明DXS是MeJA和光质等诱导子促进三角褐指藻岩藻黄素积累的关键酶之一。研究为进一步利用代谢工程手段提高藻细胞内岩藻黄素含量提供了良好的基因资源, 为深入探索三角褐指藻岩藻黄素合成的分子调控机制提供了一定的理论依据。     

三角褐指藻八氢番茄红素脱氢酶1-2基因启动子克隆和表达分析

八氢番茄红素脱氢酶(phytoene desaturase, PDS)是类胡萝卜素合成的关键酶，在光合生物的类胡萝卜素代谢调控中发挥了重要的作用。本研究根据三角褐指藻基因组数据库，克隆三角褐指藻PDS1和PDS2基因启动子序列，采用启动子缺失技术研究启动子活性，利用Plant CARE预测三角褐指藻PDS1和PDS2启动子顺式作用元件，采用qRT-PCR技术检测三角褐指藻PDS1和PDS2基因在不同胁迫下的相对表达量。结果表明，三角褐指藻PDS1和PDS2基因启动子全长分别为2 000 bp和920 bp,不同长度的5′端缺失后启动子均能驱动绿色荧光蛋白表达，具有较强启动子活性。Plant CARE分析结果表明，三角褐指藻PDS1和PDS2基因启动子中均含有与光照和植物激素响应有关的顺式作用元件。光照和植物激素胁迫处理结果表明，三角褐指藻PDS1基因受光合诱导因子(photosynthetic induction factor, PIF)的诱导表达，但在其他因子处理下表达均显著下降(P<0.05)或无显著性差异。三角褐指藻PDS2基因在PIF、红光、茉莉酸甲酯、乙酰水杨酸和脱落酸...     

Cd2+对紫球藻生长及光化学活性的影响

以紫球藻(Porphyridium purpureum)为供试材料, 研究了5个不同浓度的Cd2+对紫球藻的细胞密度、叶绿素a含量、藻红蛋白含量及ATP含量的影响, 以及对紫球藻的最大光量子产额(F_v/F_m)、实际光量子产额(YII)、相对电子传递效率(ETR)及非光化学淬灭(NPQ)的影响, 探讨了各荧光参数在不同浓度的Cd2+胁迫下的变化规律。研究结果表明, 在Cd2+胁迫的6d内, 紫球藻的生长速度显著下降, 且Cd2+的浓度越高, 生长速度下降越快; Cd2+胁迫显著的减少叶绿素a、藻红蛋白及ATP含量, 且浓度越高, 减少的幅度越大; 在Cd2+浓度低于200 μmol/L时, 紫球藻的叶绿素荧光参数F_v/F_m、YII及ETR呈现先下降后上升的趋势,而且随着胁迫时间的延长, 下降幅度逐步增大; NPQ在低浓度下(<200 μmol/L)呈现显著上升趋势, 高浓度下(>500 μmol/L)呈现显著下降趋势。因此, 水体中浓度超过50 μmol/L的Cd2+就会显著影响紫球藻的生长及光化学活性, 水生环境中不断累积的Cd2+将会对紫球藻的生态平衡产生影响。     

三角褐指藻基因枪转化体系的建立

三角褐指藻具有较高的脂肪酸含量,是一种很有潜力的生物柴油生产原料。此外,它是多不饱和脂肪酸尤其是二十碳五烯酸（EPA）重要的来源。合适转化体系的缺乏限制了通过基因工程手段对其进行改造。首次采用基因枪方法成功地将外源基因转入三角褐指藻,转化细胞经染色后呈现蓝色,表明外源报告基因β-糖苷酸酶( GUS ) 基因得到了成功的表达。同时还进行了转化参数等因素对转化效率影响的分析,优化了转化条件。结果显示最佳的转化条件为: 每60 μg钨粉包被1 μg质粒DNA,样品室真空度为27英寸汞柱,可裂膜为1500psi,受体与阻挡网距离6 cm。此外,转化载体采用了三角褐指藻内源基因fcp的启动子,实现了外源基因在细胞内的表达。通过5种基因工程中常用抗生素对三角褐指藻生长抑制的研究发现,三角褐指藻对卡那霉素、氨苄青霉素、链霉素和新霉素不敏感,500 mg/L 的卡那霉素、氨苄青霉素和新霉素,以及1000 mg/L 链霉素仍不能抑制其生长;三角褐指藻对氯霉素非常敏感,130 mg/L的氯霉素可以完全抑制其生长,其半抑制浓度为60 mg/L。这为基因工程手段改造三角褐指藻脂肪酸代谢相关途径奠定了基础。     

不同饵料对卤虫生长、总脂含量及脂肪酸组成的影响

为了提高养殖卤虫的饵料营养价值,了解其不同生长阶段营养成分变化情况,采用单因子试验研究了8种饵料（三角褐指藻、小球藻、微绿球藻、酵母液、三角褐指藻＋小球藻＋微绿球藻、三角褐指藻＋酵母液、小球藻＋酵母液和微绿球藻＋酵母液）对卤虫生长、总脂含量及脂肪酸组成的影响,结果表明：不同饵料种类对卤虫生长、总脂含量及脂肪酸组成的影响显著（P＜0.05）,增长率,以三角褐指藻＋酵母液最优;总脂含量、以三角褐指藻最优（19.67%）,除酵母液外,与其它饵料相差不显著（P＞0.05）;脂肪酸组成效果,以微绿球藻组最优（EPA：18.01%,DNA：0.55%,（n-3）HUFA：19.08%）,与三角褐指藻组相差不大（P＞0.05）,显著高于其它各组（P＞0.05）.同时以三角褐指藻为饵料,研究了卤虫不同生长阶段（体长2、4、6、8、10 mm）总脂含量、脂肪酸组成变化,结果表明：卤虫体长2～10 mm总脂含量为14.27%～20.93%,随体长的增长降低;EPA、DHA及（n-3）HUFA的含量,均随体长的增长降低,EPA含量为：10.47%～20.77%,DNA含量为：0～0.70%,（n-3）HUFA含量为：10.85%～22.01%.结论认为,卤虫以三角褐指藻或三角褐指藻＋酵母液为饵料培养营养价值最佳,其体长小于6 mm营养价值较佳.     

三角褐指藻和小角毛藻对UV-B辐射增强的生理生化响应

通过实验生态学和生物化学的方法,研究了UV-B辐射对三角褐指藻和小角毛藻的生长、叶绿素a、类胡萝卜素、丙二醛、可溶性蛋白含量和抗氧化物酶活性的影响。结果表明:(1) UV-B辐射增强抑制了2种微藻的生长,低剂量(0.75J/m²)UV-B辐射对三角褐指藻的生长具有一定刺激作用。(2) 三角褐指藻的叶绿素a含量随辐射剂量的增加先上升后下降,小角毛藻chl-a含量缓慢下降。2种微藻MDA含量随UV-B辐射剂量的增加而升高。(3) 随着辐射剂量的增加,三角褐指藻可溶性蛋白含量先稍有升高后较快下降。小角毛藻可溶性蛋白含量始终呈下降趋势。(4) UV-B辐射增强使2种微藻的SOD 、POD和CAT活性先升高后下降,小角毛藻的酶活性变化相对稳定。     

藻类种类和浓度对中华哲水蚤(Calanus sinicus)摄食和消化酶活性的影响

通过饵料浓度差法在实验条件下研究了不同浓度的金藻、三角褐指藻和巴夫藻对中华哲水蚤(Calanus sinicus)摄食和消化酶活性的影响,结果表明:不同藻类和浓度对中华哲水蚤的摄食有明显的影响.(1)中华哲水蚤对3种饵料藻的摄食存在一饱和浓度,低于饱和浓度,摄食率随着食物浓度的增加而增加;高于饱和浓度,摄食率呈下降趋势.实验浓度下,中华哲水蚤对金藻、三角褐指藻和巴夫藻的最大摄食率分别为4664、6021 cells ml-1和4524 cells ml-1.滤水率随着食物浓度的增加而呈单一性的下降.(2)中华哲水蚤消化酶活性随藻类种类和浓度的变化而变化.不同藻类和浓度下,昆布多糖酶活性都明显高于麦芽糖酶和纤维二糖酶的活性,而麦芽糖酶活性又稍高于纤维二糖酶的活性.不同藻类喂养条件下,中华哲水蚤3种消化酶的活性发生了不同程度的变化,以巴夫藻喂养时酶活性稍高.     

氮限制对硅藻三角褐指藻光系统Ⅱ光化学反应的影响

本文以硅藻三角褐指藻为实验材料,设置氮充足(882.35μmol·L~(-1))和氮限制(40μmol·L~(-1))两种营养盐供应水平进行培养,以探讨氮限制条件下三角褐指藻光系统Ⅱ(PSII)光化学反应及其对高光强的耐受性变化。结果表明:氮限制抑制三角褐指藻的生长,降低其叶绿素a含量,并加剧其受光抑制程度;通过分析快速叶绿素荧光诱导动力学曲线发现,氮限制使得电子从Q_A~-向QB的传递受阻,且高光强作用后,Q_A~-的瞬时积累进一步增加;此外,氮限制条件下,活性反应中心部分关闭,藻细胞单位反应中心吸收的能量(ABS/RC)、捕获的用于还原Q_A的能量(TRo/RC)以及耗散的能量(DI_o/RC)均明显升高;而高光的耦合作用使得PSII反应中心进一步失活;氮限制影响三角褐指藻PSII光化学反应,进而降低其对高光的耐受能力。     

外源钙对镉胁迫下南美蟛蜞菊毛状根生长、抗氧化酶活性和镉吸收的缓解效应

为了探讨外源钙对重金属镉(Cd)缓解南美蟛蜞菊Wedelia trilobata毛状根毒害的生理机理,采用溶液培养法研究了重金属Cd单独及其与Ca组合对南美蟛蜞菊毛状根生长、抗氧化酶超氧化物岐化酶(SOD)和过氧化物酶(POD)活性及对Cd2+吸收的影响。结果表明,Cd≤50μmol/L时促进毛状根生长;高于100μmol/LCd则抑制其生长,使其侧根短小,根尖变褐或变黑。与对照相比,不同浓度Cd培养的毛状根POD活性、SOD活性和MDA含量都比对照明显提高,但高于100μmol/L Cd培养的毛状根可溶性蛋白含量均比对照降低。与仅添加200μmol/L或300μmol/L Cd的毛状根相比,Cd和10~30 mmol/L Ca组合培养可促进毛状根生长,使其主、侧根变粗;提高其可溶性蛋白含量;降低其MDA含量、POD活性及SOD活性。原子吸收分光光度法测定结果表明,南美蟛蜞菊毛状根能吸收和吸附重金属Cd2+,当Cd2+浓度为100μmol/L时毛状根对Cd2+的吸收量最大,而Cd2+浓度为300μmol/L时毛状根对Cd2+的吸附量最大。外源加入10~30 mmol/L Ca2+可显著减少毛状根对Cd2+的吸收和吸附,并可调节其抗氧化酶活性,降低其膜脂过氧化水平而解除重金属镉对毛状根生长的抑制或毒害。     

三角褐指藻对黑暗胁迫的生理响应

为了研究黑暗条件对三角褐指藻生长及生化组成的影响,并探讨三角褐指藻对黑暗环境的生长适应能力,我们对该藻进行12 d的黑暗处理,着重测定了藻细胞密度、生物量、叶绿素a、可溶性糖和蛋白含量等指标。结果表明,三角褐指藻对黑暗环境表现出一定的适应性忍耐能力,在12 d的长期黑暗胁迫条件下依然可以存活,而藻细胞生化组成对黑暗的响应程度很可能是该藻得以维持细胞低水平生长的主要原因。随着黑暗处理时间的延长,三角褐指藻生长状况受抑制的程度增大,其生长及生化组成与对照组相比发生了极显著的变化。实验结束时,黑暗处理下的藻细胞密度和生物量分别降低到2.93×10⁵ cells·ml^-1和0.011 g·ml^-1,仅为对照的8.0%和37.3%。同样地,黑暗环境也明显地抑制了三角褐指藻体内生化物质的合成与积累,黑暗处理12 d时藻细胞的叶绿素a、可溶性糖和蛋白含量分别比对照降低了约89%、87%和85%。研究结果可为海洋微藻种质的筛选、种质资源库的构建及微藻生物资源的综合开发利用提供参考依据。     

Physiological and morphological effects of genetic alterations leading to a reduced synthesis of UDP-glucose in Saccharomyces cerevisiae

Yeast cells lacking UDP-Glc pyrophosphorylase (UGPase) encoded by UGP1 are not viable. Two strategies were developed to drastically reduce the intracellular concentration of UDP-Glc in order to study the consequences of this metabolic engineering on physiology and morphology. Firstly, UGP1 was placed under the strongly regulatable THI4 promoter. This resulted in a 95% reduction of UGPase activity in the presence of thiamine. The phenotypic effects of this reduction were slightly stronger than those of glucose on the GAL10/CYC1-UGP1 gene fusion [Daran et al. (1995) Eur. J. Biochem. 230, 520–530]. A further reduction of flux towards UDP-Glc was achieved by deletion of the two phosphoglucomutase genes in the ugp1 conditional strain. The growth of this new mutant strain was hardly affected, while it was extremely sensitive to cell wall interfering drugs. Surprisingly, UDP-Glc levels were reduced only by 5-fold, causing a proportional decrease in both glycogen and β-glucans. Taken altogether, these results indicate that a few percent of enzymatic activities leading to the formation of UDP-Glc appears sufficient to provide the UDP-Glc demands required for cell viability, and that the loss of function of UGP1 is lethal mainly because of the inability of yeast cells to properly form the cell wall.     

Depletion of UDP-Glucose and UDP-Galactose Using a Degron System Leads to Growth Cessation of Leishmania major

Interconversion of UDP-glucose (UDP-Glc) and UDP-galactose (UDP-Gal) by the UDP-Glc 4´-epimerase intimately connects the biosynthesis of these two nucleotide sugars. Their de novo biosynthesis involves transformation of glucose-6-phosphate into glucose-1-phosphate by the phosphoglucomutase and subsequent activation into UDP-Glc by the specific UDP-Glc pyrophosphorylase (UGP). Besides UGP, Leishmania parasites express an uncommon UDP-sugar pyrophosphorylase (USP) able to activate both galactose-1-phosphate and glucose-1-phosphate in vitro. Targeted gene deletion of UGP alone was previously shown to principally affect expression of lipophosphoglycan, resulting in a reduced virulence. Since our attempts to delete both UGP and USP failed, deletion of UGP was combined with conditional destabilisation of USP to control the biosynthesis of UDP-Glc and UDP-Gal. Stabilisation of the enzyme produced by a single USP allele was sufficient to maintain the steady-state pools of these two nucleotide sugars and preserve almost normal glycoinositolphospholipids galactosylation, but at the apparent expense of lipophosphoglycan biosynthesis. However, under destabilising conditions, the absence of both UGP and USP resulted in depletion of UDP-Glc and UDP-Gal and led to growth cessation and cell death, suggesting that either or both of these metabolites is/are essential.     

转UGPase基因喜树木材化学成分与生长速率研究

分析了田间栽培条件下2年生转UGPase基因喜树与对照株的木材化学成分与生长速率。结果表明,转UGPase基因喜树综纤维素含量达到78.87%,比对照株相比提高了2.23%;纤维素含量为36.34%,与对照株相比没有明显提高;木质素含量为15.05%,较对照株降低了1.75%;两者的灰分含量均较低且无显著差异;冷、热水抽提物含量为7.62%与10.17%,分别提高了2.04%与2.13%;1% NaOH抽提物含量为27.13%,提高了1.27%。因此,就综纤维素、木质素、灰分含量而言,转UGPase基因喜树为优质纸浆材,水抽提物和1% NaOH抽提物的含量略高,在纸浆生产中需加以重视。本文还对转UGPase基因喜树与对照株的株高、基径、生物量进行了动态监测,结果表明,从5月25日到11月10日的生长季中,其株高平均增加121 cm,对照株平均仅67.8 cm,株高生长速率提高了78.47%;基径平均增加1 792 cm,对照株平均仅0.532 8 cm,提高了236.37%;地上部分生物量的积累与对照相比提高了322.61%,即转入UGPase基因使喜树生长速率显著提高。因此,虽然转UGPase基因喜树的综纤维素和纤维素含量没有明显提高,但其生长速率快,生物量增长显著,间接提高了纤维素与喜树碱的产量。因此,转基因喜树较普通喜树更符合纸浆材速生、纤维素含量高和产量高、木质素含量低的基本要求,可在生产中进一步推广。     

Dosage suppression of the Kluyveromyces lactis zymocin by Saccharomyces cerevisiae ISR1 and UGP1

The Kluyveromyces lactis zymocin complex kills Saccharomyces cerevisiae cells in a process that involves tRNA cleavage by its tRNAse gamma-toxin subunit. In contrast to the gamma-toxin mode of action, the early steps of the zymocin response are less well characterized. Here, we present high-dosage suppressors of zymocin that encode a putative Pkc1-related kinase (ISR1) and UDP-glucose pyrophosphorylase (UGPase) (UGP1). Anti-UGPase Western blots and GAL10 - ISR1 overexpression suggest that zymocin suppression correlates with overproduction of UGPase or Isr1. As judged from protection against exo-zymocin and unaltered sensitivity to endogenous gamma-toxin, high-copy ISR1 and UGP1 operate in early, nontarget steps of the zymocin pathway. Consistent with a recent report on in vitro phosphorylation of Isr1 and UGPase by the CDK Pho85, high-copy ISR1 and UGP1 suppression of zymocin is abolished in a pho85 null mutant lacking CDK activity of Pho85. Moreover, suppression requires UGPase enzyme activity, and ISR1 overexpression also protects against CFW, a chitin-interfering poison. Our data agree with roles for UGPase in cell wall biosynthetic processes and for Isr1 in Pkc1-related cell wall integrity. In sum, high-copy ISR1 and UGP1 cells affect early steps of the zymocin response and potentially prevent the lethal K. lactis killer complex from establishing cell surface recognition and/or contact.     

Analysis of the expression of potato uridinediphosphate-glucose pyrophosphorylase and its inhibition by antisense RNA

The expression of the enzyme UDP-glucose pyrophosphorylase (UGPase; EC 2.7.7.9) from potato (Solanum tuberosum L.) was analysed with respect to sink-source interactions and potato tuber storage. The highest level of expression was found in developing tubers, the strongest sink tissue. Storage of mature tubers at low temperatures led to an increase of the steady-state level of UGPase mRNA, implicating a role of this enzyme in the process of cold-sweetening. Transgenic plants were created expressing UGPase antisensee RNA under the control of the 35S promoter of the Cauliflower Mosaic Virus with the polyadenylation signal of the octopine-synthase gene. Regenerated plants were tested for reduction of UGPase at the RNA, protein and activity levels. Plants with a 95%–96% reduction of UGPase activity in growing tubers showed no change in growth and development. Also, carbohydrate metabolism in tubers of these plants was not substantially affected, indicating that only 4% of the wild-type UGPase activity is sufficient for the enzyme to function in plant growth and development.Abbreviations cDNA copy DNA - CaMV Cauliflower Mosaic Virus - Glc1P glucose-1-phosphate - UDPGlc UDP-glucose - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - UGPase UDP-glucose pyrophosphorylase We are grateful to Dr. J.P. Spychalla (Cambridge Laboratory, Norwich, Norfolk, UK) for providing antiserum directed against the potato tuber UGPase protein. We thank J. Bergstein and B. Schäfer for photographic work, J. Dietze for plant transformation and R. Breitfeld and B. Burose for taking care of the greenhouse plants.     

Regulation of UDP-glucose pyrophosphorylase isozyme UGP5 associated with cold-sweetening resistance in potatoes

The regulation of UDP-Glc pyrophosphorylase (UGPase) isozyme, UGP5, was investigated in potato tuber. The cDNA for UGP5 was cloned into the bacterial expression vector pET21d and recombinant (RC) enzyme was expressed in E. coli (BL21 star cells). The RC-UGP5 isozyme was purified to near homogeneity using salt precipitation, hydrophobic interaction, and anion-exchange column chromatography. Kinetic analysis revealed that in the synthesis direction, K(m) values for Glc-1-P (0.83mM) and UTP (0.22mM) were similar to those observed previously with the mother tuber (MT)-UGP5. In the pyrophosphorolysis direction, the K(m) values for UDP-Glc (0.68mM) and PPi (0.56mM) were slightly higher than those observed previously. Maximum reaction velocities (V(max)) for RC-UGP5 were also elevated. Since the molecular mass, charge, and amino acid sequence of the MT- and RC-UGP5 isozymes were identical, it was assumed that altered kinetic constants may be due to an improper folding of RC-UGP5 polypeptide. Liquid chromatography-tandem mass spectrometry (LC-MS/MS) and proteomic analysis demonstrated that the UGP5 isozyme was a single polypeptide with a calculated molecular mass of 51.8kDa consisting of 477 amino acids. Native PAGE and kinetic analysis revealed that this polypeptide was monomeric in nature. Immunoblotting with specific antibodies and LC-MS/MS data indicated that UGP5 did not require any post-translational modification (e.g., phosphorylation, O-glycosylation, oligomerization/de-oligomerization, or the presence of the regulatory 14-3-3 proteins) for its regulation. Additionally, the two closely associated isozymes UGP5 and UGP6 in the cv. Snowden are likely the result of allelic differences of UGPase at a single locus.     

UGPase和反义4CL基因对转基因烟草纤维素和木质素合成的调控

用根癌农杆菌介导法将源于紫穗槐的尿苷二磷酸葡萄糖焦磷酸化酶（UGPase）基因、反义4-香豆酸辅酶A连接酶（4CL）基因以及两者的双价基因分别转移至烟草中。PCR和Southern杂交检测证实外源基因已整合到转基因烟草基因组中。测定全纤维素和Klason木质素含量的结果显示,增强UGPase基因的表达可提高转基因植株的纤维素含量,但对木质素含量没有影响;抑制4CL基因的表达可显著降低转基因植株的木质素含量,但对纤维素含量没有影响;转移双价基因的转基因植株中纤维素含量增加而木质素含量降低。     

Physicochemical and kinetic properties of unique isozymes of UDP-Glc pyrophosphorylase that are associated with resistance to sweetening in cold-stored potato tubers

Isozymes of UGPase with unique catalytic properties were purified from the cold-induced-sweetening (CIS) resistant cultivar Snowden (Solanum tuberosum). Two distinct peaks of UGPase activity were obtained when protein extracts were subjected to anion-exchange chromatography on DEAE-Sephacel. Polypeptides in the first eluted fraction (A-I) were ionically similar to the UGPase isozyme UGP3 previously purified and characterized from the cold-sweetening sensitive cultivar Norchip (Sowokinos et al. 1993, Plant Physiol 101: 1073-1080). Seventy-two percent of the total endogenous UGPase activity in Snowden (cv.) tubers, however, was found in a more basic protein fraction (A-II) that is not found in the Norchip cultivar. This study reports on the physicochemical and kinetic properties of these new polypeptides that demonstrate UGPase activity. The reaction in the direction of UDP-Glc synthesis was specific for the substrates Glc-1-P and UTP and there was an absolute requirement for Mg2+ ions. The catalytic properties of UGP5 were markedly different from UGPase isozymes previously described in terms of (1) affinity for the substrate Glc-1-P, (2) pH optimum, (3) maximum reaction velocity and (4) sensitivity to product inhibition with UDP-Glc. Chi-square analysis of fifty-four genetically diverse potato lines revealed that resistance to CIS was highly correlated with the presence of the A-II isozymes of UGPase. The kinetic properties of these unique forms of UGPase may underlie, in part, a tuber's ability to resist sweetening in the cold.