Comparison of Phycobiliproteins from Gracilaria lemaneiformis (Rhodophyceae) and Its Pigment Mutants in Spectral and Molecular Respects

Comparative studies of absorption spectra of phycobiliproteins of Gracilaria lemaneiformis Greville and its pigmental mutants were conducted in this study. The results showed that the absorption spectra of phycoerythrins ( PE) from different material changed significantly, while those of phycocyanins (PC) and allophycocyanins (APC) were basically similar. In order to disclose the essence of die difference, partial sequences of die subunit genes of PE of Qingdao strain of G. lemaneiformis (qd) and its pigmental mutants were determined. The amino acid sequences were deduced and used to explain spectral shifts of PE from the pigmental mutants. The amino acid sequences of PE resembled each other, and several residues changed among qd and its pigmental mutants. Residue substitutions were found in a region consisting of amino acids which determined are secondary structure and subunits interactions, thus might influence the confirmation and interaction of subunits, and further caused spectral deviation.

Pigmentation Restored in Mutant Laboratory Strain of the Lady Beetle Coleomegilla maculata through Dietary Supplementation

A laboratory colony of Coleomegilla maculata (DeGeer), ye, selected for a pigmentation deficiency, was restored to near wild type cuticle coloration by adding crushed heads and wings of the red colored parental strain to the diet. While the wings and other colored portions of the cuticle re-gained the red color, the eyes of the pigmentation deficient insects were not changed from the pale mutant form. Plant derived carotenes lycopene and beta-carotene did not restore the mutant beetles to a visibly distinguishable red color. An additional pigmentation deficient mutant strain, gold, partially recovered red cuticle color when provided with diet containing pigmented insect particles. This work represents the first rescue of a color phenotype in a lady beetle.

Pigmentation Restored in Mutant Laboratory Strain of the Lady Beetle <i>Coleomegilla maculata</i>through Dietary Supplementation

A laboratory colony of Coleomegilla maculata (DeGeer), ye, selected for a pigmentation deficiency, was restored to near wild type cuticle coloration by adding crushed heads and wings of the red colored parental strain to the diet. While the wings and other colored portions of the cuticle re-gained the red color, the eyes of the pigmentation deficient insects were not changed from the pale mutant form. Plant derived carotenes lycopene and beta-carotene did not restore the mutant beetles to a visibly distinguishable red color. An additional pigmentation deficient mutant strain, gold, partially recovered red cuticle color when provided with diet containing pigmented insect particles. This work represents the first rescue of a color phenotype in a lady beetle.

珍珠芦荟失绿突变体‘MT-1’的农艺性状、解剖结构、光合特性和代谢组特征分析

为阐明珍珠芦荟叶色突变的变异机制,以珍珠芦荟(Aristaloe aristata)叶色失绿突变体‘MT-1’及其叶色正常种质‘WT-18’为试材,对其表型特征、叶片超微结构、光合色素含量、叶绿素荧光参数、差异代谢产物等方面进行了对比研究。结果表明,与‘WT-18’相比,突变体‘MT-1’从幼叶开始呈现出黄化条斑现象,且株型变小、生长缓慢;气孔数量少且小,形状由长方形变成正方形;叶绿体数量及内部片层数量变少、体积也明显变小;光合色素(叶绿素a、叶绿素b和类胡萝卜素)含量和叶绿素荧光动力参数(F_o、F_m、F_v/F_m、ФPSⅡ、qP、qN和ETR)均显著降低。‘MT-1’和‘WT-18’的代谢产物差异明显,KEGG代谢通路分析表明,大多数差异代谢物富集到氨基酸代谢、糖代谢、脂类代谢、核酸代谢、次级代谢产物生物合成等途径。因此,叶绿体相关基因的改变可能是发生叶色失绿突变的重要原因。

Genetics and Characteristics of a Pigmentation Defective Laboratory Strain of the Lady Beetle, Coleomegilla maculata

Beetles in the family Coccinellidae, commonly known as ladybugs, lady beetles, or ladybirds, are easily identifiable and popular beneficial insects. Current research aims to support conservation efforts of beneficial insects in agroecosystems by exploring genetic processes related to nutrition. As a part of this research, colonies of Coleomegilla maculata have been maintained in culture and inbred over many generations since 2009. One result of this inbreeding has been the discovery of novel morphological phenotypes unique to laboratory strains or present in wild populations at such low levels that they have not yet been described. One such phenotype is described here. The strain described here, ye (yellow elytra and eyes) was characterized with classical Mendelian breeding and digital image analysis. This phenotype differs from wild populations by possessing yellow pigment in the elytra and pale grey to white eyes. In contrast, wild populations of C. maculata possess pink or red pigmented elytra with black spots, and black eyes. C. maculata is not known to exhibit polymorphism in the field. Inheritance is autosomal and recessive. This species was not previously known to exhibit the dramatic variation of color described here. The strain is stable in the homozygous recessive form, and retains laboratory rearing characteristics similar to the wild type laboratory strain.

Development of a SCAR Marker for Discrimination of a Thai Jasmine Rice (<i>Oryza sativa</i>L. cv. KDML105) Mutant, BKOS6, and Associated with Purple Color Trait in Thai Jasmine Rice-Related Varieties

The potential of SCAR marker for discrimination of a Thai jasmine rice (Oryza sativa L. cv. KDML 105) mutant, BKOS6, obtained from ion-beam-induced mutation, was evaluated. The improved rice variety, BKOS6, exhibited many remarkable characteristics which fitted the multiple cropping system characteristics of progressive agriculture including photoperiod insensitivity, early flowering, short in stature, and purple pigment accumulation in pericarp. The BKOS6 rice grain extract has already been proved that it exhibited higher antioxidant properties than the KDML 105 and other tested rice grain extracts. In this study, the BKOS6 specific SCAR marker was developed by HAT-RAPD analysis of rice genomic DNA. The marker was successfully used to identify BKOS6 variety and its hybrid varieties containing purple pigment accumulation in plant tissues. Moreover, it was found that this marker could be used to detect other purple pigmented rice varieties that genetically related to Thai jasmine rice. Recently, a wide variety of anthocyanin-based foods are believed to provide significant potential health benefits, and become more attractive. KDML 105 is also a Thai premier fragrant rice variety which is one of the main varieties of country’s rice export. Thus this molecular marker could be useful for commercial and breeding purposes of BKOS6 mutant and other developed varieties from KDML 105 which contain anthocyanin accumulation.

坛紫菜品系间杂交分离色素突变体及其特性的初步研究

以野生选育的坛紫菜(Porphyra haitanensis)为母本,诱变选育全棕红的品系为父本进行杂交实验,从杂交子代大量叶片中,筛选出1株褐黄色素突变体、1株翠绿色与野生色相嵌的嵌合体和1株褐绿色与野生色相嵌的嵌合体。通过酶法分离突变体的营养细胞,单性生殖获得丝状体;分别使丝状体成熟并放散壳孢子,然后单株培养和筛选获得褐黄、翠绿和褐绿色子代叶状体。实验进行50 d。结果:(1)褐黄色突变体藻蓝蛋白和别藻蓝蛋白含量低;孢子囊枝的细胞较小,且大量形成时间比亲本晚15 d;幼苗培养初期日平均生长量仅为(1.22±0.28)cm,当叶片长到60 cm左右时生长优势逐步凸显,日平均生长量可达(7.50±1.18)cm;(2)翠绿色丝状体容易成熟,发育方式特殊,营养藻丝不经过藻丝加粗阶段,直接由球形细胞发育成孢子囊枝和壳孢子囊;翠绿色叶状体藻红蛋白含量低,仅有(5.513 0±1.049 6)mg/g(干品);叶状体生长快速,60 cm长的藻体日平均生长量高达(11.95±2.33)cm;(3)褐绿色突变体藻蓝蛋白、别藻蓝蛋白和藻红蛋白这3种色素蛋白和叶绿素的含量均较低;藻丝细胞短且细,叶状体生长速度较慢。

水稻“斑马叶”叶绿素含量及几种酶活性的变化

以具“斑马叶”性状的水稻 110 3S、武金 4B以及对照武金 3B为材料 ,研究了该性状表达过程中叶片叶绿素、蛋白质含量及几种酶活性的变化 .结果表明 ,性状表达期叶片叶绿素、蛋白质含量减少 ,过氧化氢酶 ( CAT)和超氧化物歧化酶 ( SOD)活性降低 ,过氧化物酶 ( POD)活性上升 ;随着叶片复绿 ,各项指标又回复到低温处理前的水平 .该性状的表达是由于阶段性叶绿素代谢异常所致 ,它不仅与叶绿素含量有关而且与 POD、CAT。

^(60)Co-γ射线诱变条斑紫菜丝状体的研究

利用^（６０）Ｃｏ－γ射线对条斑紫菜Ｐｏｒｐｈｙｒａ ｙｅｚｏｅｎｓｉｓ 自由丝状体进行诱变。经照射后，丝 状体受到严重损伤，但部分仍具钻入贝壳的能力。部分丝状体发生颜色变异，而且后代叶状 体也表现为相同的颜色。部分未变异的丝状体在放散出壳孢子，并萌发成幼苗后也表达了 颜色变异。低剂量的照射可以促进藻体的生长，并产生形态上的变异。对照射藻体的海上栽 培实验也进行了观察和测量。

^(60)Co-γ射线对条斑紫菜(Porphyra yezoensis)的诱变效果与色素突变体分离

用60Co-γ射线辐照处理野生型条斑紫菜的壳孢子萌发体以获得色素变异细胞,随后用酶解法获得单离的变异细胞进行个体再生培养,从中分离出不同的条斑紫菜色素突变体。结果表明,叶状体经剂量分别为100、300、500、700和900Gy的γ射线辐照后再培养1周,均出现了多种色素变异细胞,随后,它们逐渐分裂成为变异细胞块。在0—500Gy辐照剂量范围内,色素变异细胞块的百分率随着辐照剂量的增加而增加,但增至700Gy时,变异细胞块的百分率反而下降,说明500Gy是最合适的剂量。从单离变异细胞的再生叶状体中分离出桔红、紫红、桔黄和墨绿等颜色的单色变异体,并获得了它们的丝状体纯系。各变异品系的F1叶状体均为单色,其颜色与各自的母本叶状体相同,表明它们是稳定突变体。各色素突变品系的叶状体活体吸收光谱不仅与野生型品系有明显的差异,而且各突变品系之间也存在较大的差异。

四种植物生长激素对海带雌配子体克隆生长发育的影响

以海带（Ｌａｍｉｎａｒｉａｊａｐｏｎｉｃａ）雌配子体克隆ＬＨ１０品系为材料，用４种植物生长激素：三十烷醇（ＴＡ）、２，４－二氯苯氧乙酸（２，４－Ｄ）、吲哚乙酸（ＩＡＡ）和腐植酸钠加以处理，对其生长发育进行了研究。结果表明，它们的最佳生长浓度分别为：ＴＡ，０．０１ｍｇ／Ｌ；２，４－Ｄ０．５ｍｇ／Ｌ；ＩＡＡ，０．５ｍｇ／Ｌ；腐植酸钠，０．５ｍｇ／Ｌ；最佳发育浓度分别为：ＴＡ，０．０１ｍｇ／Ｌ；２，４－Ｄ，１ｍｇ／Ｌ；ＩＡＡ，０．１ｍｇＬ－１；腐植酸钠，０．０５ｍｇ／Ｌ。

江蓠属藻胆蛋白的研究──Ⅰ 诱变、突变体筛选及藻胆蛋白的光谱特性

用N-甲基-N′-硝基-N-亚硝基胍（MNNG）对龙须菜配子体进行诱变处理，并筛选出色素突变体。又以真江蓠、细基江篱繁枝变型、龙须菜及其突变体为材料进行了藻胞蛋白的提取、纯化及藻胆蛋白光谱特性的研究。结果表明，江蓠属三个物种藻胆蛋白的含量有明显差异，龙须菜的野生型藻体与突变体之间藻胆蛋白含量的差异比不同物种之间的差异更为显著。江蓠属三个物种中藻胆蛋白的吸收光谱中以藻红蛋白（PE）变化最大：细基江蓠繁枝变型PE的吸收光谱有二峰一肩，属Ⅰ型R-PE，而真江蓠和龙须菜的PE的吸收光谱有三个峰，属Ⅱ型R－PE：龙须菜的不同突变型藻体的吸收光谱也有Ⅰ型和Ⅱ型R－PE之分。不同物种藻蓝蛋白也有R－PC和C－PC的差异，异藻蓝蛋白的吸收光谱及三种藻胆蛋白的荧光发射光谱也略有变化。并以光合进化的观点分析了本文的实验结果。

坛紫菜人工色素突变体的诱变与分离

坛紫菜叶状体经一定剂量的60Co-γ射线辐射再培养一段时间后,出现了少量色素体颜色发生变异的细胞,它们呈点状无规则地镶嵌在野生型细胞中。培养3周后,色素变异细胞分裂并形成了不同颜色的细胞块, 其颜色呈桔红、桔黄、浅黄褐、浅红、紫红、紫褐、黄绿、绿色等。在辐射剂量0-1 100 Gy范围内,叶状体上色素变异细胞块的出现频率随着辐射剂量的增加而增加;但辐射剂量增至1400 Gy时,色素变异细胞块出现的频率反而下降,说明1 100 Gy是合适的辐射剂量。在同一个叶状体的不同部位上色素变异细胞块出现的频率是不同的,从基部到稍部,随着部位的上移而逐渐增加。用酶解法把含色素变异细胞的叶状体细胞单个分离出来并进行离体培养,在它们的再生体中,出现了多种单色的色素突变叶状体,从中分离到tan(红褐色)、bor(深结红色)、ceb(紫红色)、hon(枯草色)、cac(深黄绿色)等不同颜色的纯色突变体。从各单色突变体中分离出来的丝状体,其颜色与各自的叶状体相同。各突变体的丝状体成熟后,放散的壳孢子长成单色的F1叶状体,其颜色与各自最初的母体叶状体相同,说明所得到的上述突变体是稳定的色素突变体。

氩离子激光照射对类球红细菌的诱变效应及对辅酶Q_(10)产生量的影响

以低产量辅酶Q10类球红细菌为亲本,以氩离子激光为诱变源,对其幅照诱变,结果发现:亲本株发生了明显的诱变效应,出现了不同的色素突变表型。诱变后的色素突变株不仅遗传性状稳定,且辅酶Q10产量比亲本株有明显提高。对其中的黄色突变株发酵液进行辅酶Q10提取及测定,结果显示:其辅酶Q10产量比亲本株提高102.10%,经发酵条件初步优化,其最高产量可达26.39 mg/L发酵液。

坛紫菜减数分裂位置的杂交试验分析

利用坛紫菜人工色素突变体与野生型进行杂交试验,通过观察F1叶状体中是否出现颜色分离和颜色嵌合体来证明坛紫菜减数分裂发生的确切位置。以红色型人工色素突变体(SPY1和R10)作为母本,其特征:叶状体呈红色或桔红色,藻体薄而弹性差,无边缘刺;以野生型(wt)作为父本,其特征:叶状体呈棕绿色,藻体厚而富有弹性,有丰富的边缘刺。在杂交组SPY1(♀)×wt(♂)和R10(♀)×wt(♂))的F1叶状体中,均出现了2种亲本色和2种新颜色,它们分别为红色(R,母本色),野生色(W,父本色),浅红色(R′,比R色稍浅)和似野生色(W′,比野生色稍红)。4种颜色在F1叶状体上,出现了分离并形成了呈直线型排列的不同色块,从而产生了大量由2～4个色块组成的颜色嵌合体;单个嵌合体上的色块数最多为4块。在颜色嵌合体中,R和R′2种色块的藻体薄而弹性差,无边缘小刺,而W和W′2种色块的藻体厚而弹性好,富有边缘刺。在F1叶状体中,颜色嵌合体占95.2%～96.7%,单色叶状体只占3.3%～4.8%。上述结果说明,坛紫菜杂合丝状体产生的壳孢子,其萌发时进行的最初两次细胞分裂是减数分裂,它所产生的4个子细胞继续分裂,最终发育成含2～4个色块组成的颜色嵌合体;2种新颜色是由于在减数分裂的第一次分裂时发生了染色体交换和重组所产生的。本文使用的两个色素突变体,除含2个或2个以上的颜色变异基因外,还含有分别与藻体厚薄和边缘刺出现相关的变异基因,并且它们与颜色变异基因是连锁的。F1颜色嵌合体中的重组色块在3种主要光合色素和色素蛋白的含量、生长速度和成熟早晚等方面均表现出比亲本色块更好的特性,暗示利用色素突变体杂交方法有可能培育出坛紫菜的优良品系。

坛紫菜不同色素突变体的初步研究

初步探讨了坛紫菜Porphyra haitanensis褐色、褐绿色、翠绿色、红棕色、棕褐色、桔红色和紫色7种色素突变体的子一代叶状体形态特征、生长及4种主要色素含量的变化。3～4cm长的不同色泽幼苗经20d培养后的结果显示:(1)各色素突变体从长度、宽度、鲜重量和细胞厚度方面较野生坛紫菜均具有显著优势;在培养时间内,各色素突变体的长度日增长量均显著高于野生型坛紫菜;褐绿色、棕褐色和红棕色突变体在鲜重日增重率上表现出明显的优势,在第11～15天所有色素突变体的平均日增重率均高于野生型;(2)红棕色、棕褐色和紫色突变体的总藻胆蛋白含量明显高于野生型。紫色突变体的藻红蛋白、藻蓝蛋白和别藻蓝蛋白含量均为最高,其中藻红蛋白、别藻蓝蛋白含量为野生型的3倍。叶绿素含量均无明显变化。本研究结果为有效利用坛紫菜的不同色素突变体进行种质改良奠定了良好基础。

控制水稻金黄色颖壳与节间基因OsCAD2的图位克隆

【目的】水稻色素不仅对其自身生长发育有重要生理作用,而且在水稻育种、农副产品改良等方面运用比较广泛。对水稻色素相关基因进行表型分析和基因定位,为进一步研究色素代谢途径及调控机理奠定基础。【方法】利用EMS诱变粳稻长粒粳(CLJ),在突变体库内筛选到一个金黄色颖壳与节间突变体gh881;在成熟期,测定野生型与gh881的主要农艺性状;将gh881与野生型及中恢8015杂交,观察BC1F1及F1植株表型,并对BC1F2及F2表型分离进行卡方检验,对gh881进行遗传分析;利用F2群体和图位克隆的方法对gh881突变基因进行定位;采用q PCR检测颖壳颜色相关基因在gh881与野生型不同发育时期的幼穗、节间以及剑叶叶鞘的相对表达量。【结果】与野生型相比,突变体的颖壳与节间均呈金黄色;除单株有效穗数外,gh881突变体的株高、每穗总粒数及实粒数、结实率和千粒重等性状均极显著降低。遗传分析和基因定位结果表明,gh881的突变表型受1对隐性核基因控制,位于第2染色体短臂,并最终将该基因精细定位于标记FH-13和RH-25之间,物理距离约33.2 kb,该区域中包含4个开放阅读框(ORFs)。【结论】序列分析结果表明,发现其中一个编码肉桂醇脱氢酶(CAD)的基因OsC AD2(Os02g0187800)的3 563 bp处发生了1个单碱基突变(G转换为A),导致该基因编码区的第297位氨基酸由甘氨酸突变为天冬氨酸,由此认为该突变体为OsC AD2基因单碱基突变的新等位基因。q RT-PCR结果表明,突变体的节间中OsCAD2相对表达量极显著下调,而在剑叶叶鞘及穗部则基本都是极显著增加,其他相关基因也发生显著变化,证实OsCAD2是木质素代谢中的重要基因,且可能与其他相关基因存在反馈调节。

高产红曲黄色素菌株的选育

利用紫外、硫酸二乙酯、氯化锂和亚硝基胍复合诱变的方法,选育到一株高产黄色素的红曲霉突变株MYM2。经过稳定性实验证明,诱变得到的菌株稳定性较好,液态发酵试验黄色素色价达到100U/mL以上,黄色素色调达到3.5左右。此黄色素在300nm^600nm波长之间只有一个在410nm附近的最大吸收峰,在pH3~8之间稳定性较好。当pH小于3时,红曲黄色素不稳定,黄色素溶液变混浊,放置后有沉淀产生。

出芽短梗霉产色素能力弱化菌株的筛选

出芽短梗霉在发酵过程中会产生一种与黑色素相似的黑色物质 ,并且这种物质会牢固地粘附在短梗霉多糖上 .对出芽短梗霉Aureobasidium pullulanB 1菌株进行6 0 Co诱变 ,获得了一株产色素能力缺失型菌株Co3,其菌落和发酵液颜色为白色或淡绿色 .红外光谱和磁核共振图谱表明该菌株的产物与标准短梗霉多糖样品有相同的结构 .

用RAPD技术检测龙须菜色素突变体基因组的变化

龙须菜野生型于 1 996年采自青岛太平角 ,经性别、相态确认后进行实验 ;突变株为野生型经诱变的配子体。用RAPD技术检测野生型龙须菜及 3株色素突变体的基因组特性及差异。共选用 1 0个随机引物进行扩增 ,产生 1 67条DNA片段 ,检测到 38个多态位点 ,并显示gr1 84在 0 .66、0 .79、2 .0kb处的特征带。结果表明 ,野生型株藻与突变株基因组有明显差异 ,在 3个突变藻株中 ,有 2株绿色突变体的基因组更相近。