衣藻叶绿体遗传转化的研究

叶绿体遗传转人是近几年发展起来的新领域。本文主要介绍了叶绿体遗传转化的特点、基本原理和衣藻叶绿体遗传转化的方法与技术;     

Chloroplast envelope proteins are encoded by the chloroplast genome of Chlamydomonas reinhardtii.

To characterize envelope proteins encoded by the chloroplast genome, envelopes were isolated from Chlamydomonas reinhardtii cells labeled with [35S] sulfate while blocking synthesis by cytoplasmic ribosomes. One and two-dimensional gel electrophoresis of envelopes and fluorography revealed four highly labeled proteins. Two with masses of 29 and 30 kDa and pI 5.5 were absent from the stroma and thylakoid fractions, while the others at 54 kDa, pI 5.2 and 61 kDa, pI 5.4 were detected there in smaller amounts. The 29- and 30-kDa proteins were associated with outer envelope membranes separated from inner envelope membranes after chloroplast lysis in hypertonic solution. A 32-kDa protein not labeled by [35S]sulfate was found exclusively in the inner membrane fraction, suggesting the existence of a phosphate translocator in C. reinhardtii. To identify envelope proteins exposed on the chloroplast surface, isolated active chloroplasts were surface-labeled with 125I and lactoperoxidase. The 54-kDa, pI 5.2 protein as well as a protein corresponding to either of the 29- or 30-kDa proteins described above were among the labeled components. These results show that envelope proteins of C. reinhardtii are encoded by the chloroplast genome and two are located on the outer envelope membranes.     

Engineering the Chloroplast Encoded Proteins of Chlamydomonas

Over a decade ago (1988), John Boynton and colleagues successfully transformed the chloroplast genome of chlamydomonas for the first time by complementation of a chloroplast deletion mutant. Since the first demonstration of chloroplast transformation the function and structure of many chloroplast encoded subunits of the photosynthetic apparatus has been characterized by site-directed mutagenesis. With the completion of the sequencing of the Chlamydomonas chloroplast genome the genetic tools are now in hand to characterize structure-function relationships for each of the chloroplast-encoded proteins of the photosynthetic apparatus.     

Behavior of Chloroplast Nucleus during Chloroplast Development and Degeneration in Chlamydomonas reinhardii

Changes in morphology of chloroplast nuclei (cp-nuclei), totalcp-DNA content, number of cp-nuclei, oxygen-evolution activityand chlorophyll (a and b) content were examined during the degenerationand development of chloroplasts, using Chlamydomonas reinhardiicells which had been incubated on solid medium for various periods. Under 4'-6-diamidino-2-phenylindole (DAPI) epifluorescence microscopy,each cell that had been incubated for 7 days had one cell nucleus,one cup-shaped chloroplast and about 10 small, dispersed cp-nucleiin the chloroplast. One day after incubation of these cellson fresh medium, the cell volume and cp-nuclei increased insize 2-3 fold, but rapidly decreased in size after cell division.After about 7 days of incubation, cells ceased to divide andcp-nuclei began to associate with each other. At about 20 daysthey formed a ring-shaped structure surrounding the pyrenoid,followed by condensation into one cp-nuclear particle near thepyrenoid. When 41-day-old cells, having only one cp-nucleus,were reinoculated on fresh solid medium, the cp-nucleus increasedin size 2–3 fold, divided into several cp-nuclear particlesand then dispersed into the chloroplast, forming a bead-likestructure, before cell division. From microscopic fluorometry,a 4-fold increase in total cp-DNA content per chloroplast, withoutan increase in the number of cp-nuclear particles per chloroplast,occurred one day after the start of the experiment and one dayafter reinoculation of 41-day-old cells onto fresh medium. Theprocess of condensation of dispersed cp-nuclear particles intoone cp-nucleus during degeneration of the chloroplast was notaccompanied by any change in total cp-DNA content per chloroplast.A large peak of oxygen-evolution (0.6–0.9 pmoles/cell/hour)was seen one day after inoculation and reinoculation of thecells. The chlorophyll content (a+b) was high (1.2–2.2pg/cell) during the first week of incubation, after which itgradually decreased. (Received December 18, 1985; Accepted April 2, 1986)     

Chloroplast DNA Replication Is Regulated by the Redox State Independently of Chloroplast Division in Chlamydomonas reinhardtii

Chloroplasts arose from a cyanobacterial endosymbiont and multiply by division. In algal cells, chloroplast division is regulated by the cell cycle so as to occur only once, in the S phase. Chloroplasts possess multiple copies of their own genome that must be replicated during chloroplast proliferation. In order to examine how chloroplast DNA replication is regulated in the green alga Chlamydomonas reinhardtii, we first asked whether it is regulated by the cell cycle, as is the case for chloroplast division. Chloroplast DNA is replicated in the light and not the dark phase, independent of the cell cycle or the timing of chloroplast division in photoautotrophic culture. Inhibition of photosynthetic electron transfer blocked chloroplast DNA replication. However, chloroplast DNA was replicated when the cells were grown heterotrophically in the dark, raising the possibility that chloroplast DNA replication is coupled with the reducing power supplied by photosynthesis or the uptake of acetate. When dimethylthiourea, a reactive oxygen species scavenger, was added to the photoautotrophic culture, chloroplast DNA was replicated even in the dark. In contrast, when methylviologen, a reactive oxygen species inducer, was added, chloroplast DNA was not replicated in the light. Moreover, the chloroplast DNA replication activity in both the isolated chloroplasts and nucleoids was increased by dithiothreitol, while it was repressed by diamide, a specific thiol-oxidizing reagent. These results suggest that chloroplast DNA replication is regulated by the redox state that is sensed by the nucleoids and that the disulfide bonds in nucleoid-associated proteins are involved in this regulatory activity.Chloroplasts are semiautonomous organelles that possess their own genome, which is complexed with proteins to form nucleoids and also certain machinery needed for protein synthesis, as is the case in prokaryotes. It is generally accepted that chloroplasts arose from a bacterial endosymbiont closely related to the currently extant cyanobacteria (Archibald, 2009; Keeling, 2010). In a manner reminiscent of their free-living ancestor, chloroplasts proliferate by the division of preexisting organelles that are coupled to the duplication and segregation of the nucleoids (Kuroiwa, 1991) and have retained the bulk of their bacterial biochemistry. However, chloroplasts have subsequently been substantially remodeled by the host cell so as to function as complementary organelles within the eukaryotic host cell (Rodríguez-Ezpeleta and Philippe, 2006; Archibald, 2009; Keeling, 2010). For example, most of the genes that were once in the original endosymbiont genome have been either lost or transferred into the host nuclear genome. As a result, the size of the chloroplast genome has been reduced to less than one-tenth that of the free-living cyanobacterial genome. Thus, the bulk of the chloroplast proteome consists of nucleus-encoded proteins that are translated on cytoplasmic ribosomes and translocated into chloroplasts. In addition, chloroplast division ultimately came to be a process tightly regulated by the host cell, which ensured permanent inheritance of the chloroplasts during the course of cell division and from generation to generation (Rodríguez-Ezpeleta and Philippe, 2006; Archibald, 2009; Keeling, 2010).Chloroplast division is performed by constriction of the ring structures at the division site, encompassing both the inside and the outside of the two envelopes (Yang et al., 2008; Maple and Møller, 2010; Miyagishima, 2011; Pyke, 2013). One part of the division machinery is derived from the cyanobacterial cytokinetic machinery that is based on the FtsZ protein. In contrast, other parts of the division machinery involve proteins specific to eukaryotes, including one member of the dynamin family. The majority of algae (both unicellular and multicellular), which diverged early within the Plantae, have just one or at most only a few chloroplasts per cell. In algae, the chloroplast divides once per cell cycle before the host cell completes cytokinesis (Suzuki et al., 1994; Miyagishima et al., 2012). In contrast, land plants and certain algal species contain dozens of chloroplasts per cell that divide nonsynchronously, even within the same cell (Boffey and Lloyd, 1988). Because land plants evolved from algae, there is likely to have been a linkage between the cell cycle and chloroplast division in their algal ancestor that was subsequently lost during land plant evolution. Our recent study showed that the timing of chloroplast division in algae is restricted to the S phase by S phase-specific formation of the chloroplast division machinery, which is based on the cell cycle-regulated expression of the components of the chloroplast division machinery (Miyagishima et al., 2012).Because chloroplasts possess their own genome, chloroplast DNA must be duplicated so that each daughter chloroplast inherits the required DNA after division. However, it is still unclear how the replication of chloroplast DNA is regulated and whether the replication is coupled with the timing of chloroplast division, even though certain studies have addressed this issue, as described below.Bacteria such as Escherichia coli and Bacillus subtilis possess a single circular chromosome. In these bacteria, the process of DNA replication is tightly coupled with cell division (Boye et al., 2000; Zakrzewska-Czerwińska et al., 2007), in which the initiation of replication is regulated such that it occurs only once per cell division cycle (Boye et al., 2000). In contrast, cyanobacteria contain multiple copies of their DNA (e.g. three to five copies in Synechococcus elongatus PCC 7942; Mann and Carr, 1974; Griese et al., 2011). In some obligate photoautotrophic cyanobacterial species, replication is initiated only when light is available (Binder and Chisholm, 1990; Mori et al., 1996; Watanabe et al., 2012). Replication is initiated asynchronously among the multiple copies of the DNA. Although the regulation of the initiation of DNA replication is less stringent than that in E. coli and B. subtilis, as described above, a recent study using S. elongatus PCC 7942 showed that this replication peaks prior to cell division, as in other bacteria.Chloroplasts also contain multiple copies of DNA (approximately 1,000 copies; Boffey and Leech, 1982; Miyamura et al., 1986; Baumgartner et al., 1989; Oldenburg and Bendich, 2004; Oldenburg et al., 2006; Shaver et al., 2008). In algae, chloroplast DNA is replicated in a manner that keeps pace with chloroplast and cell division in order to maintain the proper DNA content per chloroplast (i.e. per cell). In contrast, in land plants, the copy number of DNA in each chloroplast (plastid) changes during the course of development and differentiation, although contradictory results were reported about leaf development (Lamppa and Bendich, 1979; Boffey and Leech, 1982; Hashimoto and Possingham, 1989; Kuroiwa, 1991; Rowan and Bendich, 2009; Matsushima et al., 2011). Previous studies that synchronized the algal cell cycle by means of a 24-h light/dark cycle showed that chloroplast DNA is replicated only during the G1 phase, after which it is separated into daughter chloroplasts during the S phase by chloroplast division, implying that chloroplast DNA replication and division are temporally separated (Chiang and Sueoka, 1967; Grant et al., 1978; Suzuki et al., 1994). However, under these experimental conditions, G1 cells grow and the chloroplast DNA level increases during the light period. Cells enter into the S phase, chloroplast DNA replication ceases, and the chloroplasts divide at the beginning of the dark period. Thus, it is still unclear whether chloroplast DNA replication is directly controlled by the cell cycle, as is the case in chloroplast division, or chloroplast DNA replication occurs merely when light energy is available.We addressed this issue using a synchronous culture as well as a heterotrophic culture of the mixotrophic green alga Chlamydomonas reinhardtii. The results show that chloroplast DNA replication occurs independently of either the cell cycle or the timing of chloroplast division. Instead, it is shown that chloroplast DNA replication occurs when light is available in photoautotrophic culture and even under darkness in heterotrophic culture. Further experimental results suggest that chloroplast DNA replication is regulated by the redox state in the cell, which is sensed by the chloroplast nucleoids.     

外源基因在莱茵衣藻叶绿体中的表达

把莱茵衣藻(Chlamydomonas reinhardtii)叶绿体作为生物反应器来表达外源基因具有广阔的应用前景。人们利用莱茵衣藻叶绿体表达体系已成功表达多种重组蛋白,其中包括人类药用蛋白。综述了莱茵衣藻叶绿体转化的方法、影响外源基因表达的主要因素以及外源基因在莱茵衣藻叶绿体表达研究进展。     

衣藻叶绿体表达系统的研究

真核藻类作为一种新型的蛋白表达系统,因其培养方法简单,成本低廉并且能大规模繁殖,最近几年成为人们关注的焦点.作为一种模式生物,单细胞的真核生物莱茵衣藻已经成为人们研究的重点.外源蛋白不仅能在衣藻核中进行表达而且也能在叶绿体中表达,但衣藻叶绿体的表达系统较之核表达有巨大的优越性.在到目前为止,已经有许多的药用蛋白在莱茵衣藻的叶绿体中成功表达的报道,证明了莱茵衣藻叶绿体作为生物反应器的能力.将对衣藻叶绿体的表达做详细的描述.     

Potassium Fluxes in Chlamydomonas reinhardtii (II. Compartmental Analysis)

42K+ and 86Rb+ were used to determine the subcellular distribution of potassium in Chlamydomonas reinhardtii by compartmental analysis. In both wild type and a mutant strain, three distinct compartments (referred to as I, II, and III) were apparent. Using 42K+, we found that these had half-lives for K+ exchange of 1.07 min, 12.8 min, and 2.9 h, respectively, in wild-type cells and 0.93 min, 14.7 min, and 9.8 h, respectively, for the mutants. Half-lives were not significantly different when 86Rb+ was used to trace K+. Compartments I and II probably correspond to the cell wall and cytoplasm, respectively. Based on the lack of a large central vacuole in Chlamydomonas, the effect of a dark pretreatment on the kinetic properties of compartment III and the similarity between the [K+] of compartment III and that of isolated chloroplasts, this slowly exchanging compartment was identified as the chloroplast. Growth of wild-type cells at 100 [mu]M (instead of 10 mM K+) caused no change of cytoplasmic [K+] but reduced chloroplast [K+] very substantially. The mutants failed to grow at 100 [mu]M K+.     

Localization of Nitrogen-Assimilating Enzymes in the Chloroplast of Chlamydomonas reinhardtii

The specific activities of nitrate reductase, nitrite reductase, glutamine synthetase, glutamate synthase, and glutamate dehydrogenase were determined in intact protoplasts and intact chloroplasts from Chlamydomonas reinhardtii. After correction for contamination, the data were used to calculate the portion of each enzyme in the algal chloroplast. The chloroplast of C. reinhardtii contained all enzyme activities for nitrogen assimilation, except nitrate reductase, which could not be detected in this organelle. Glutamate synthase (NADH- and ferredoxin-dependent) and glutamate dehydrogenase were located exclusively in the chloroplast, while for nitrite reductase and glutamine synthetase an extraplastidic activity of about 20 and 60%, respectively, was measured. Cells grown on ammonium, instead of nitrate as nitrogen source, had a higher total cellular activity of the NADH-dependent glutamate synthase (+95%) and glutamate dehydrogenase (+33%) but less activity of glutamine synthetase (−10%). No activity of nitrate reductase could be detected in ammonium-grown cells. The distribution of nitrogen-assimilating enzymes among the chloroplast and the rest of the cell did not differ significantly between nitrate-grown and ammonium-grown cells. Only the plastidic portion of the glutamine synthetase increased to about 80% in cells grown on ammonium (compared to about 40% in cells grown on nitrate).     

Chloroplast Development in the Chloroplast Ribosome Deficient Mutant (y-1 ac-20) of Chlamydomonas reinhardtii

To study the participation of chloroplast protein synthesisduring the three phases [Matsuda (1974) Biochim. Biophys. Acta366:45] of the greening process in Chlamydomonas reinhardtiiy-1, the greening characteristics in the low-chloroplast ribosomemutant y-1 ac-20 were compared with those in the y-1. In thedouble mutant cells Chl synthesis proceeded with an extendedlag and without a second transition point. The development ofpotential for rapid Chl synthesis (P-factor formation) was alsodelayed. Furthermore, PS I activity increased significantly,whereas PS II activity developed very little during greeningof the double mutant cells. The results indicate that greeningin double mutant cells occurs with no apparent late phase. (Received November 26, 1984; Accepted February 25, 1985)     

Palmelloid Formation of Chlamydomonas II. Mechanism of Palmelloid Formation by Organic Acids

To clarify the mechanism of palmelloid formation by organic acids, the dissociation of the suspension of palmelloids in different media was studied. It was found that the palmelloids can be dissociated by the calcium ion at the low concentration of 6.8 × 10^-5M, but not by the magnesium ion. The dissociation is suppressed by the phosphate ion. Furthermore, Chlamydomonas cells grown in media containing EDTA or GEDTA or in media deficient in calcium, are induced to form palmelloids. These results indicate that the effect of organic acids on the formation of palmelloids are due to their ability to chelate with calcium.     

拟南芥叶绿体分裂突变体pdl37的基因鉴定与分析

pd137是经甲基磺酸乙脂（ethyl methane sulphonate, EMS）诱变并通过筛选得到的一个拟南芥叶绿体分裂突变体。该突变体的叶绿体表型与野生型相比有很大差异： 叶绿体面积显著增大, 细胞中叶绿体数量明显减少。遗传分析显示pd137的突变表型受隐性单基因控制。本研究通过遗传作图将该突变基因粗定位于拟南芥2号染色体的分子标记CH2-13.70和CH2-16.0区间内。该区间内已知的与叶绿体分裂相关的基因只有FtsZ2-1。对FtsZ2-1基因的测序结果显示pd137突变体的FtsZ2-1基因第505位碱基发生了无义突变, 使蛋白质翻译提前终止。该突变还严重影响了FtsZ2-1基因的mRNA水平。转基因互补实验进一步验证了该突变体表型是由于FtsZ2-1基因突变引起。本项工作为研究叶绿体分裂的机制提供了新材料和一些有用的线索。     

拟南芥叶绿体分裂突变体cpd111的基因定位与分析

通过EMS(ethyl methane sulphonate)诱变从拟南芥(Arabidopsis thaliana)突变体库中筛选到一个叶绿体分裂突变体(c)hloro(p)last (d)ivision 111 (cpd111).遗传学分析表明,该突变体的表型是单基因控制的隐性性状.与野生型相比,突变体植物细胞的叶绿体数量少,叶绿体形态和大小多样化,并且细胞体积与叶绿体数量之间无相关性.利用图位克隆的方法确定cpd111的突变基因为FtsZ1.进一步的分析表明,该突变影响FtsZ7基因mRNA的正常剪切和稳定性,使蛋白质翻译提前终止,最终导致叶绿体分裂异常.该工作为研究FtsZ1在叶绿体分裂中的作用提供了新的材料和线索.     

莱茵衣藻叶绿体生物反应器研究进展

莱茵衣藻(Chlamydomonas reinharditi)是一种遗传机制已研究比较清楚的模式植物。近年来,生物反应器是当今世界上各国生物技术研究的一个热点,随着生物技术的发展,已成功实现衣藻作为生物反应器生产重组蛋白及抗体,生产的部分产品已经实现了商品化,与其他生物反应器相比,其在外源基因表达水平和转基因植物安全性等方面有明显的优势,尤其是在控制转基因沉默和遗传稳定性方面展示了极大的优越性。因此,莱茵衣藻是一种具有很好发展前景的生物反应器,必将在未来的药用蛋白生物技术领域发挥重要作用。主要对提高基因在莱茵衣藻叶绿体中表达的策略,转化技术的特点及其未来的发展前景等方面进行了简单评述。