一种高效提取普通小球藻叶绿体DNA的新方法

本文采用尿素-月桂酰肌氨酸钠（urea-sarkosyl）法, 用于分离带有坚硬细胞壁小球藻的高纯度叶绿体DNA （cpDNA）。将对数生长期的小球藻收集后置于冰上研磨, percoll密度梯度离心收集叶绿体层, 显微观察表明叶绿体经梯度离心后形态完整。采用尿素-月桂酰肌氨酸钠法、蛋白酶K消化及酚/氯仿/异戊醇抽提, 获得了高纯度的cpDNA。检测结果显示, cpDNA分子长度为22 kb, A260：A280值为1.87±0.01, 产率达（2.52±0.01） μg？g-1 （DW）; cpDNA编码的16S rDNA扩增呈阳性, 而由细胞核编码的18S rDNA扩增呈阴性。表明cpDNA纯度高, 没有受到核基因组DNA的污染, 符合小球藻cpDNA高通量测序的要求。同时, 该方法也适合提取具有相似细胞壁成分的其他微藻的基因组DNA和cpDNA。     

窄叶鲜卑花(Sibiraea angustata)nrDNA ITS和cpDNA trnL-F序列分子进化特点的分析

应用PCR产物直接测序法分析了窄叶鲜卑花居群间nrDNA(核糖体DNA)ITS序列和cpDNA(叶绿体DNA)trnL-F的碱基差异,并与cpDNAtrnS-G序列和rpl20-rps12序列进行比较,从而初步研究两套植物基因组的变异速率。采用改良的CTAB法从硅胶干燥的窄叶鲜卑花叶片中提取总DNA,并对nrDNA ITS和cpDNAtrnL-F区域进行扩增、纯化、测序。nrDNA ITS序列共有601 bp,有变异位点3处,变异位点百分率为0.05%,(G+C)含量为41.4%。cpDNAtrnL-F序列共有927 bp,有变异位点1处,变异位点百分率0.01%,(G+C)含量为32.6%,两种序列的核苷酸多样性非常低。比较发现,窄叶鲜卑花nrDNA ITS区域较cpDNAtrnS-G序列和rpl20-rps12序列保守,变异速率较慢,比cpDNAtrnL-F序列变异速率稍快。通过对ITS序列单倍型(haplotype)进行分析发现,窄叶鲜卑花现有分布范围经历了居群近期范围扩张,与叶绿体基因组(trnS-G和rpl20-rps12序列)得出的结论一致。因此,窄叶鲜卑花nrDNA ITS序列适合该种的谱系地理学研究。     

Detection and characterization of a plastid envelope DNA-binding protein which may anchor plastid nucleoids.

Chloroplast DNA (cpDNA) binds to the envelope membrane of actively dividing chloroplasts (plastids) in young pea leaves. South-western blotting was used to identify and characterize the protein involved in the binding of cpDNA to the envelope membrane. A 130 kDa protein in the inner chloroplast (plastid) envelope membrane binds specific sequences within the cpDNA. These included a 0.41 kbp sequence located upstream of the psaAB gene, a 0.57 kbp sequence located downstream of the petA gene and a 1.2 kbp sequence located within the rpoC2 gene. The protein was detected in the envelope membrane of young pea leaves in which the cpDNA had been located by fluorescence microscopy at the chloroplast periphery, whereas it was undetectable in mature leaves. We therefore propose that the 130 kDa protein is involved in the binding of cpDNA to the envelope membrane, and named it plastid envelope DNA-binding protein.     

茶树叶绿体及其蛋白的分离研究

茶树叶片叶绿体的有效分离纯化是进行茶树叶绿体代谢组学和蛋白质组学研究的基础.本文以茶树鲜叶为材料,通过叶绿体得率、希尔反应等纯度和完整度指标,比较了Percoll密度梯度离心法和蔗糖密度梯度离心法对叶绿体分离纯化的效果;通过蛋白质含量和SDS-PAGE电泳图谱,比较了涨破法和冻融法对叶绿体蛋白的提取效果.结果发现Per...     

南川绣线菊和细枝绣线菊分子水平研究

对6个野外居群(南川绣线菊和细枝绣线各3个)36个个体进行叶绿体(chloroplast,cp)DNA trnL-trnF片断测序分析.在南川绣线菊中发现了3个单倍型(Ros1-Ros3),在细枝绣线菊中发现了2个单倍型(Myr1-Myr2).两个种的序列联合分析对位排列后得到850 bp,共有9个变异位点,其中一个为碱基插入或缺失,另外8个为碱基置换,变异位点的百分率为0.11.对单倍型的遗传多样性分析表明同一区域亲缘关系相近的单倍型发生于同一居群中,并且存在着明显的分子系统地理学关系.以蔷薇科另两个外属植物Rosa californica 和 Sorbaria sorbifolia为外类群构建这两个种的最大简约(MP)树、最大似然(ML)树及贝叶斯树,结果获得了分辨良好的种间关系树.这表明在分子水平上两个种之间存在明显的差异,这与形态学上的表现是相一致的.遗传多样性分析结果表明了cpDNA trnL-trnF 片段对于绣线菊属的分子地理学研究还是比较有效的,可以通过进一步的大面积采样和分析来揭示植物的遗传结构、冰期避难所等问题.     

Loss or retention of chloroplast DNA in maize seedlings is affected by both light and genotype

We examined the chloroplast DNA (cpDNA) from plastids obtained from wild type maize (Zea mays L.) seedlings grown under different light conditions and from photosynthetic mutants grown under white light. The cpDNA was evaluated by real-time quantitative PCR, quantitative DNA fluorescence, and blot-hybridization following pulsed-field gel electrophoresis. The amount of DNA per plastid in light-grown seedlings declines greatly from stalk to leaf blade during proplastid-to-chloroplast development, and this decline is due to cpDNA degradation. In contrast, during proplastid-to-etioplast development in the dark, the cpDNA levels increase from the stalk to the blade. Our results suggest that DNA replication continues in the etioplasts of the upper regions of the stalk and in the leaves. The cpDNA level decreases rapidly, however, after dark-grown seedlings are transferred to light and the etioplasts develop into photosynthetically active chloroplasts. Light, therefore, triggers the degradation of DNA in maize chloroplasts. The cpDNA is retained in the leaf blade of seedlings grown under red, but not blue light. We suggest that light signaling pathways are involved in mediating cpDNA levels, and that red light promotes replication and inhibits degradation and blue light promotes degradation. For five of nine photosynthetic mutants, cpDNA levels in expanded leaves are higher than in wild type, indicating that nuclear genotype can affect the loss or retention of cpDNA.     

The structure of chloroplast DNA molecules and the effects of light on the amount of chloroplast DNA during development in Medicago truncatula

We used pulsed-field gel electrophoresis and restriction fragment mapping to analyze the structure of Medicago truncatula chloroplast DNA (cpDNA). We find most cpDNA in genome-sized linear molecules, head-to-tail genomic concatemers, and complex branched forms with ends at defined sites rather than at random sites as expected from broken circles. Our data suggest that cpDNA replication is initiated predominantly on linear DNA molecules with one of five possible ends serving as putative origins of replication. We also used 4',6-diamidino-2-phenylindole staining of isolated plastids to determine the DNA content per plastid for seedlings grown in the dark for 3 d and then transferred to light before being returned to the dark. The cpDNA content in cotyledons increased after 3 h of light, decreased with 9 h of light, and decreased sharply with 24 h of light. In addition, we used real-time quantitative polymerase chain reaction to determine cpDNA levels of cotyledons in dark- and light-grown (low white, high white, blue, and red light) seedlings, as well as in cotyledons and leaves from plants grown in a greenhouse. In white, blue, and red light, cpDNA increased initially and then declined, but cpDNA declined further in white and blue light while remaining constant in red light. The initial decline in cpDNA occurred more rapidly with increased white light intensity, but the final DNA level was similar to that in less intense light. The patterns of increase and then decrease in cpDNA level during development were similar for cotyledons and leaves. We conclude that the absence in M. truncatula of the prominent inverted repeat cpDNA sequence found in most plant species does not lead to unusual properties with respect to the structure of plastid DNA molecules, cpDNA replication, or the loss of cpDNA during light-stimulated chloroplast development.     

Replication of chloroplast, mitochondrial and nuclear DNA during growth of unirradiated and UVB-irradiated Arabidopsis leaves

Replication of Arabidopsis nuclear, mitochondrial and chloroplast DNA (ncDNA, mtDNA, cpDNA) was assayed by measuring respective changes in copies per leaf, employing quantitative PCR (QPCR) analysis with genome-specific primer pairs. All three genomes showed parallel increases during growth of cotyledons and 5th leaves in planta, maintaining approximately 13 mtDNA copies and 280 cpDNA copies per haploid nuclear genome. Detached 5th leaves, which showed good growth and DNA replication on agar plates, were irradiated at (DNA-effective) UV-B fluences of 1.3-5.0 kJ m-2 and incubated under blue (photorepair-active) plus gold light or gold light only. Under blue light, replication of all genomes after all UV fluences was approximately as efficient as replication in unirradiated leaves. UV-irradiated leaves showed little growth under gold light only; 5 kJ m-2 stopped replication of all three genomes, 2.5 kJ m-2 stopped only cpDNA replication, and 1.3 kJ m-2 only delayed cpDNA replication. Immunoassays showed that 5 kJ m-2 induced about 1.2 cyclobutane pyrimidine dimers and 0.1 [6-4]photoproducts per kbp of bulk DNA, and that both photoproducts were completely removed during 2-3 days under blue light, suggesting efficient photorepair of at least ncDNA and cpDNA. The evidence for efficient photorepair of organellar DNA contrasts with previous studies of irradiated 5-day-old seedlings, and with the apparent absence of Arabidopsis photolyases bearing transit peptides.     

Simultaneous purification of chloroplast and mitochondrial DNA without isolation of intact organelles from green carrot tissue and suspension cultures

We report here the simultaneous purification of chloroplast (cpDNA) and mitochondrial DNA (mtDNA) from green tissue and suspension cultures of carrot without organelle isolation. This method is based on isolating total nucleic acids from frozen tissue and separating the nuclear, chloroplast and mitochondrial fractions using sequential isopycnic sedimentation in two gradients of cesium chloride containing bisbenzamide. From 10 g of mature carrot leaves, 10 to 30μg of organelle DNA was consistently recovered from mature carrot leaves, while 30 to 50 μg was recovered from suspension cells. The method can be used to isolate chloroplast and mitochondrial DNAs from single plants without sacrificing the individual.     

Artificial leaf aids analysis of chlorophyll fluorescence and P700 absorbance in studies involving microalgae

Measuring chlorophyll fluorescence and P700 absorbance has been widely used to study photosynthesis in both terrestrial plants and algae. However, in order to apply these measurement techniques to study microalgae, a concentrated suspension of algae, which is usually prepared by centrifugation, is required. In this study, instead of using centrifugation, we concentrated microalgae on a nitrocellulose membrane using filtration to create an ‘artificial leaf’ before analysis. Overall, we were able to generate values of the appropriate photosynthetic parameters that were comparable to those obtained when chlorophyll fluorescence and P700 absorbance were measured following centrifugation. There were no statistically significant differences (P > 0.05) between the artificial leaf method and the traditional cuvette method for determining chlorophyll fluorescence or P700 absorbance at appropriate chlorophyll concentrations. We were also able to reduce background noise by using a filter membrane as a carrier. Therefore, an artificial leaf has the potential to be a valuable tool for phycologists interested in studying microalgal photosynthesis by enabling them to eliminate tedious centrifugation steps. In addition, fluorometers commonly used for studying the leaves of higher plants will also be suitable for studying microalgae.     

Species relationships in the Hordeum murinum aggregate viewed from chloroplast DNA restriction fragment patterns

Summary Three annual widespread species of Hordeum were investigated by the fragment pattern method on their chloroplast (cp) DNA. The species were H. glaucum, H. leporinum and H. murinum; H. vulgare was surveyed for comparison. Twelve restriction enzymes were used, nine recognizing 6 bp, one 5 bp and two 4 bp, thus, randomly surveyed, a total of 2,113 bp or 1.6% of the cp genome. Differences in patterns were found in three enzymes, HindIII, CfoI and MspI. CfoI characterizes H. glaucum from the other two species. HindIII and MspI revealed polymorphisms within species. These results confirm previous numerical taxonomic relationships among these three closely related species. Furthermore, cpDNA polymorphism in Hordeum is discussed in view of earlier reports on cpDNA polymorphism in H. vulgare. The taxonomic implications of cpDNA polymorphism are discussed after reviewing several articles using the fragment pattern method on cpDNA. The importance of using material from several populations representative of a species is stressed.     

Chloroplast DNA levels and the control of chloroplast division in light-grown wheat leaves

Plastids at different stages of development were isolated from light-grown wheat (Triticum aestivum, var. Maris Dove) seedling leaves, and the average chloroplast DNA (cpDNA) per plastid at each developmental stage was measured directly. In the earliest stages of development, the number of plastids per cell and the amount of cpDNA per cell increased with cell age, but cpDNA per plastid remained constant at between 800 and 1,000 genome copies per plastid. After this phase, plastids per cell continued to increase, but cpDNA per plastid decreased. Subsequently, both plastids per cell and cpDNA per plastid remained constant as cell age increased, the final DNA content being approximately 300 genome copies per plastid. These results are related to previous reports of cpDNA changes during the development of dicotyledonous plants, and to theories about the regulation of chloroplast numbers per cell.     

An Improved Protocol for Intact Chloroplasts and cpDNA Isolation in Conifers

Background

Performing chloroplast DNA (cpDNA) isolation is considered a major challenge among different plant groups, especially conifers. Isolating chloroplasts in conifers by such conventional methods as sucrose gradient and high salt has not been successful. So far, plastid genome sequencing protocols for conifer species have been based mainly on long-range PCR, which is known to be time-consuming and difficult to implement.

Methodology/Principal Findings

We developed a protocol for cpDNA isolation using three different conifer families: Araucaria angustifolia and Araucaria bidwilli (Araucariaceae), Podocarpus lambertii (Podocarpaceae) and Pinus patula (Pinaceae). The present protocol is based on high salt isolation buffer followed by saline Percoll gradient. Combining these two strategies allowed enhanced chloroplast isolation, along with decreased contamination caused by polysaccharides, polyphenols, proteins, and nuclear DNA in cpDNA. Microscopy images confirmed the presence of intact chloroplasts in high abundance. This method was applied to cpDNA isolation and subsequent sequencing by Illumina MiSeq (2×250 bp), using only 50 ng of cpDNA. Reference-guided chloroplast genome mapping showed that high average coverage was achieved for all evaluated species: 24.63 for A. angustifolia, 135.97 for A. bidwilli, 1196.10 for P. lambertii, and 64.68 for P. patula.

Conclusion

Results show that this improved protocol is suitable for enhanced quality and yield of chloroplasts and cpDNA isolation from conifers, providing a useful tool for studies that require isolated chloroplasts and/or whole cpDNA sequences.     

Less Pollen-Mediated Gene Flow for More Signatures of Glacial Lineages: Congruent Evidence from Balsam Fir cpDNA and mtDNA for Multiple Refugia in Eastern and Central North America

The phylogeographic structure and postglacial history of balsam fir (Abies balsamea), a transcontinental North American boreal conifer, was inferred using mitochondrial DNA (mtDNA) and chloroplast DNA (cpDNA) markers. Genetic structure among 107 populations (mtDNA data) and 75 populations (cpDNA data) was analyzed using Bayesian and genetic distance approaches. Population differentiation was high for mtDNA (dispersed by seeds only), but also for cpDNA (dispersed by seeds and pollen), indicating that pollen gene flow is more restricted in balsam fir than in other boreal conifers. Low cpDNA gene flow in balsam fir may relate to low pollen production due to the inherent biology of the species and populations being decimated by recurrent spruce budworm epidemics, and/or to low dispersal of pollen grains due to their peculiar structural properties. Accordingly, a phylogeographic structure was detected using both mtDNA and cpDNA markers and population structure analyses supported the existence of at least five genetically distinct glacial lineages in central and eastern North America. Four of these would originate from glacial refugia located south of the Laurentide ice sheet, while the last one would have persisted in the northern Labrador region. As expected due to reduced pollen-mediated gene flow, congruence between the geographic distribution of mtDNA and cpDNA lineages was higher than in other North American conifers. However, concordance was not complete, reflecting that restricted but nonetheless detectable cpDNA gene flow among glacial lineages occurred during the Holocene. As a result, new cpDNA and mtDNA genome combinations indicative of cytoplasmic genome capture were observed.     

The hierarchical spatial distribution of chloroplast DNA polymorphism across the introduced range of Silene vulgaris

Silene vulgaris was introduced into North America sometime prior to 1800. In order to document the population structure that has developed since that time, collections were made from 56 local populations distributed among 9 geographical regions in eastern North America. Individual plants were characterized for chloroplast DNA (cpDNA) haplotype by restriction fragment size analysis of four noncoding regions of cpDNA amplified by polymerase chain reaction. A total of 19 cpDNA haplotypes were detected using this method. The overall gene diversity of 0.85 is quite similar to the diversity detected in these same regions of cpDNA in a previously published sample of S. vulgaris taken from across much of Europe. The spatial distribution of the North American cpDNA diversity was quantified by hierarchical F-statistics that partitioned the genetic variance into variation among local populations within regions, and variation among regions. The average FST among populations within regions was 0.66 and the FST among regions was 0.09. The among-region variation was due to both differences among regions in the frequency of two most common haplotypes, and to the presence of a number of region-specific haplotypes. In order to test for isolation by distance at the regional level, FST values were calculated for all possible pairs of regions, and regressed against the geographical distance between those regions. There was no evidence for isolation by distance. It is suggested that the local population structure is generated by recent extinction/colonization dynamics, and that the among-region structure reflects demographic events associated with range expansion following introduction to North America.     

On chloroplast DNA variations in the olive ( Olea europaea L.) complex: comparison of RFLP and PCR polymorphisms

Previous papers have dealt with olive chloroplastic DNA (cpDNA) variation revealed using several methods (RFLPs, PCR-RFLPs and microsatellites) and have led to different conclusions. This paper aims to reconsider these divergences. A Southern approach was applied to reveal polymorphism. We used chloroplast DNA of Phillyrea media as a probe. Based on these data, only four chlorotypes were identified in the olive complex. The number of detected lineages was lower than reported in the literature using a direct cpDNA RFLP approach, and was insufficient to distinguish the North African subspecies europaea, maroccana, guanchica and laperrinei. Furthermore, one individual considered belonging to the subspecies laperrinei was questionable. Using other cpDNA and mitochondrial DNA (mtDNA) polymorphisms - based on PCR and RFLP methods, respectively - we showed that this individual displays the cytoplasmic lineage CE1-ME1 characteristic of most Eastern mediterranean cultivars and of Olea europaea subsp. laperrinei from Hoggar. However, based on RAPDs, this individual appeared as mislabelled and probably corresponded to a Mediterranean cultivar or a feral form. In addition, we checked O. e. subsp. laperrinei herbarium samples using two cpDNA microsatellites, which revealed polymorphisms. These also supported that both populations from Niger and Algeria displayed a chlorotype related to CE1. Consequently, based on cpDNA, the relationships of O. e. subsp. laperrinei from Hoggar with a Mediterranean lineage appeared well supported, whereas the South West Moroccan and Macaronesian olives appeared in a different clade using both mtDNA and cpDNA polymorphisms. We conclude that methods based on PCR reveal more polymorphisms in the cpDNA and lead to more-reliable results that the classical RFLP method.     

Comparison of Two Methods for Preparing Mitochondria from Tomato Leaves to Study the Ascorbate-Glutathione Cycle Activity

Mitochondria were purified from tomato leaves by a differential centrifugation method and a Percoll density-gradient method. A comparative study on the ascorbate-glutathione cycle activity revealed that there was no difference in the specific activity of the antioxidative enzymes and ascorbate and glutathione concentrations between mitochondria prepared by these two methods. However, the contents of dehydroascorbic acid and oxidised glutathione in Percoll-separated organelles were 260 and 210 %, respectively, of those found in mitochondria purified by the differential centrifugation method.     

Multiple hybridization in the Aristolochia kaempferi group (Aristolochiaceae): evidence from reproductive isolation and molecular phylogeny

Hybridization via distributional changes should be an important factor for plant speciation. Previous cpDNA analyses of the Aristolochia kaempferi group, comprising six taxa in East Asia, showed a distinct phylogeographic structure resulting from distributional changes brought about by paleoclimatic oscillations. However, the cpDNA phylogeny was incongruent with morphologically defined taxa. To explore the evolutionary processes responsible for the inconsistency between cpDNA and morphology, we made artificial crosses and performed phylogenetic analyses using multiple nuclear markers. All crosses among different taxa or cpDNA clades set fruit, if crossing direction is not considered. The five nuclear phylogenies mostly did not support either the taxa or the cpDNA clades. A combined analysis of cpDNA and the PI exon revealed the two major lineages in the group, lacking a prezygotic isolating barrier between them. However, an asymmetric prezygotic isolating barrier occurs between populations of the Japanese main islands and of other areas that belong to different cpDNA subclades. It seems reasonable to conclude that the development of a prezygotic isolating mechanism is not necessarily proportional to the degree of genetic divergence. These results suggested that species boundaries within the group are blurred due to speciational processes associated with multiple hybridization and introgression resulting from repeated contacts among differentiated populations.     

Soluble peroxidase in fluid from the intercellular spaces of tobacco leaves

A high proportion of the soluble peroxidase of tobacco (Nicotiana tabacum L. var. Bottom Special) leaves is found in the fluid obtained by centrifugation of a buffer solution previously infiltrated into the intercellular spaces. Only a very small amount of the cytoplasmic enzyme, glucose 6-phosphate dehydrogenase, is present in this fluid. Specific activity data suggest that an active process is responsible for the transfer of soluble peroxidase to the intercellular space and that the intercellular fluid fraction is not simply composed of material moving out of leaf cells by diffusion. The centrifugation method is a satisfactory means of isolating diluted intercellular fluid for biochemical and physiological investigations.     

Introgression explains incongruence between nuclear and chloroplast DNA-based phylogenies in Allium section Cepa

Phylogenetic relationships between species of Allium section Cepa and A. rqylei (section Rhizirideum) have been inferred from nuclear DNA variation (RAPDs; nDNA dataset) and from morphological, pollen epidermis texture, chromosomal and chemical variation (supranuclear dataset). These sets were complemented with data, taken from the literature, on cpDNA variation and crossability. The trees produced with the supranuclear, nDNA and cpDNA datasets were compared by using the topology of the most parsimonious tree of one dataset as the constraint for the construction of a most parsimonious tree of another dataset. The accuracy of the trees were evaluated by calculating several Consistency and Incongruence Indices. The constrained tree of supranuclear-nDNA datasets showed the highest index values. The tree topologies of the supranuclear and cpDNA datasets were the least similar. The cpDNA tree and crossability dendrograms were identical. The most important difference between the nDNA-supranuclear trees and the cpDNA-crossability trees pertains to the position of Allium roylei , which is much closer to the clade A. cepa/A. vavilovii in the cpDNA tree than in the nDNA tree. This difference is considered to be the result of chloroplast capture from one species to another after an introgression event. A shorter distance between species inferred from a cpDNA tree than from a nDNA or comparable tree might be indicative for the level of crossability.