质体样细胞器APICOPLAST起源的分子证据评述

顶复合器门的原生动物（Apicomplexan protozoa）含有一个高度退化的质体样（plastid-like）细胞器,定名为apicoplast。Apicoplast的进化起源是一个长期激烈争论的问题,尽管使用了多种分子技术,但尚未取得一致的结论,以致成为质体起源研究的典型案例。文章评述了apicoplast起源研究的分子证据,分析了新的分子证据的可能来源,为进一步研究提供线索。     

系统发育分析指示细菌向Apicoplast的水平基因转移

顶复合器门的原生动物(Apicomplexan protozoa)含有一个高度退化的质体样(plastid-like)细胞器,定名为apicoplast。来自apicoplast的c／pC基因和它在其他质体和细菌中的同源物用来重建apicoplast的系统发育史。使用邻接法(Neighbor-Joining)、最小进化法(Minimum Evolution)、最大简约法(Maximum Pamimony)和最大似然法(Maximum Likelihood)建立进化树。此外为了避免由于序列之间相似的碱基组成而引起的虚假聚类,建立了基于LogDet距离的核苷酸NJ树;以及为了避免由于在核苷酸和氨基酸水平上的突变饱和而引起的长分枝吸引(Long Branch Attraction,LBA),建立了基于非饱和位点的核苷酸和氨基酸序列的系统发育树。重建结果强有力地支持apicoplast和细菌B．buigorferi之间的单系(monophyly)起源关系,也强化了apicoplasst属于混合基因组的假设,并且提供了对这个混合基因组起源的新的认识。     

B染色体起源的研究进展

B染色体(简写为Bs)起源的传统观点是认为它起源于携带者所在物种的基因组.目前又发现了许多新的证据来推测Bs的起源.它可能具有两种起源:种内起源和种间起源(起源于另一物种的基因组),且有证据表明同一物种的Bs可能是多次起源,同时对Bs的起源机制也作了总结.认为B8起源的研究已取得了一定的进展,但要给Bs起源下一个确切的结论仍需要大量的实验证据.     

被子植物花的起源:假说和证据

达尔文的 令人讨厌之谜 ,即被子植物的起源和早期演化 ,一直是植物系统学研究领域的热点 .被子植物区别于其它植物类群的一个显著特征就是花 ,因此 ,解决被子植物的起源之谜很大程度上取决于对被子植物花器官起源的研究 .对被子植物花器官的详尽研究已经在形态、解剖、古植物、形态发生、分子等方面积累了大量的证据 ,植物学家基于这些证据为被子植物花器官的起源提出了各种各样的解释 .综述了迄今为止被子植物花器官起源的主要学说流派 ,如 :真花学说、假花学说、生殖叶学说、生殖茎节学说、生花植物学说、新假花学说、古草本学说和 ANITA学说等 .根据研究手段和获得证据的方式 ,作者将被子植物花器官起源研究划分为 5个阶段 ,并简要阐述了各个阶段的代表学说和主要研究特点     

被子植物起源研究中几种观点的思考

对被子植物起源研究中的几种观点进行了讨论。(1)由于被子植物存在着一组共同的性状,它们不可能是从不同祖先起源的,而是有着共同的祖先。被子植物是一个单源起源的类群。现存被子植物分类系统是依据包括形态学(广义)、分子系统学、古植物学和植物地理学等的综合性状建立的,只能表示出现存类群的亲缘关系并且追溯到它们最近的祖先。人们现在还不可能建立一个包括全部已绝灭的类群和现代生存类群的谱系发生系统。因此,现存被子植物分类系统只能看作是“亲缘”系统。(2)分析了用于推测被子植物起源时间的分子、化石和地理分布证据。我们认为,要确定被子植物起源时间,植物化石是一类重要证据,但化石只能说是植物本身可保存部分和当时当地所提供的化石条件的综合反映,它们不可能就是植物类群或种的起源时间。人们还必须考虑到化石本身的演化历史。应用分子钟也是一种手段,但误差比较大。如果我们除了利用上述两种资料之外,根据植物类群的现代分布格局及其形成,把植物的演化同地球的历史和板块运动联系起来,以推断它们起源的时间,这无疑会增加其可信度。通过对56个种子植物不同演化水平的重要科属地理分布的研究结果,我们曾提出被子植物的起源时间可能要追溯到早侏罗世,甚至晚三叠世。(3)分析了基于分子证据所提出的被子植物基部类群——ANITA成员(包括无油樟科Amborellaceae、睡莲科Nymphaeaceae、八角目Illiciales、早落瓣科Trimeniaceae、木兰藤科Austrobaileyaceae)的性质,讨论了ANITA成员在现代几个被子植物分类系统中的系统位置的不同观点,评价了它们的形态学(广义)性状。指出ANITA的成员由于包含大量的祖征,是属于原始的类群。但由于它们的共有衍征很少,如花粉球形,说明它们在被子植物演化早期就分道扬镳了,沿着不同的传代线分化。因此ANITA是一个源于不同传代线的复合群。     

真核生物中原核生物基因的来源被揭示

<正>多年来,人们一直认为真核生物基因组中所见的原核生物基因是在一个原核细胞器的内共生之后到达那里的。但最近的研究证据表明,在真核生物之间以及在原核生物和真核生物之间也存在实质性的横向基因转移。对细菌、古菌和真核生物基因组所做的这项分析,没有发现连续横向基因转移对真核基因内容的演化具有可以检测得到的累积影响的证据。相反,真核生物是在广泛的差异基因(differential gene)丢失之后、在相对于线粒体和质体起源的两次"演化涌入"事件中获得其原核生物基因的。     

适应辐射类群穇属的系统学研究进展

综合花序拓扑学、比较形态学、分子系统发育、细胞遗传学等资料,对适应辐射类群穆属(Eleusine Gaertn.)的系统学研究进展进行了述评.穆属系统位置--Eleusiinae亚族成员得到分子系统发育证据的支持.该属具有3种花序类型、7个基因组类型、多倍体均由二倍体杂交起源、C4植物高度适应半湿润-半干旱镶嵌气候等特征.据可靠化石记载和现代地理分布推断,穆属很可能起源于东非,时间是晚中新世,而适应辐射则发生在上新世-中新世间隔.总的来说,分子系统发育、细胞遗传学、古地质、古气候数据的整合研究能够为穆属多倍体起源和谱系多样化历史提供令人信服的证据.     

被子植物花的起源：假说和证据

达尔文的“令人讨厌之谜”,即被子植物的起源和早期演化,一直是植物系统学研究领域的热点。被子植物区别于其它植物类群的一个显著特征就是花,因此,解决被子植物的起源之谜很大程度上取决于对被子植物花器官起源的研究,对被子植物花器官的详尽研究已经在形态、解剖、古植物、形态发生、分子等方面积累了大量的证据,植物学家基于这些证据为被子植物花器官的起源提出了各种各样的解释。综述了迄今为止被子植物花器官起源的主要学说流派,如：真花学说、假花学说、生殖叶学说、生殖茎节学说、生花植物学说、新假花学说、古草本学说和ANITA学说等。根据研究手段和获得证据的方式。作者将被子植物花器官起源研究划分为5个阶段,并简要阐述了各个阶段的代表学说和主要研究特点。     

书刊介绍

这本书是1979年4月26—28日在西德Spitzingsee举行的一次学术讨论会的论文集·由Elsevier North—Holland Biomedical出版,主编是R.N.Timmis(西德马克斯·普兰克分子遗传研究所)和A.Puhler(西德埃尔兰根大学)。本书分两大部分:一是综述性论文包括①、质体分类、不相容性分群(N.Datta);②、质体不相容性机制(K.N.Timmis);③、质体之间的分子相互关系(P.Broda);④、质体DNA复制(C.M.     

文昌鱼抗金葡菌感染差减文库的构建及免疫相关基因分析

适应性免疫的起源一直是免疫学研究的关键问题.文昌鱼被认为是最接近于脊椎动物的祖先 自从被发现以来一直是研究脊椎动物起源与进化机制的经典模式动物.为了在文昌鱼中寻找适应性免疫系统的分子证据,采用金黄色葡萄球菌感染文昌鱼以调查免疫的起源.应用抑制性差减杂交(SSH)技术,通过对差减文库克隆序列的测定,共获得588个表达序列标签(EST).对这些EST进行生物信息学分析和进一步功能分类,发现了一些免疫上调基因,如免疫调控基因、凋亡相关基因、细胞黏附相关基因、转录相关基因、信号传导相关基因等,以及一些非免疫相关基因;这些基因在文昌鱼中绝大多数为首次报道.金黄色葡萄球菌差减文库的成功构建,为调查文昌鱼抗细菌感染的分子事件提供了重要线索,对于这些新发现基因的进一步研究将有助于深入了解免疫系统起源与进化的机制.     

Identification of Plasmodium falciparum apicoplast-targeted tRNA-guanine transglycosylase and its potential inhibitors using comparative genomics,molecular modelling,docking and simulation studies

tRNA modifications play an important role in the proper folding of tRNA and thereby determine its functionality as an adaptor molecule. Notwithstanding the centrality of this basic process in translation, a major gap in the genomics of Plasmodium falciparum is unambiguous identification of enzymes catalysing the various tRNA modifications. In this study, tRNA-modifying enzymes of P. falciparum were annotated using homology-based approach. Based on the presence of these identified enzymes, the modifications were compared with those of prokaryotic and eukaryotic organisms. Through sequence comparison and phylogenetic analysis, we have identified P. falciparum apicoplast tRNA-guanine 34 transglycosylase (TGT, EC: 2.4.2.29), which shows evidence of its prokaryotic origin. The docking analysis of the modelled TGT structures revealed that binding of quinazolinone derivatives is more favourable with P. falciparum apicoplast TGT as compared to human TGT. Molecular dynamic simulation and molecular mechanics/generalized Born surface area analysis of the complex confirmed the greater binding affinity of the ligand in the binding pocket of P. falciparum TGT protein. Further, evolutionary patterning analysis identified the amino acids of P. falciparum apicoplast TGT that are under purifying selection pressure and hence can be good inhibitor-targeting sites. Based on these computational studies, we suggest that P. falciparum apicoplast tRNA-guanine 34 transglycosylase can be a promising drug target.     

Evolution of the apicoplast and its hosts: from heterotrophy to autotrophy and back again

The photosynthetic origin of apicomplexan parasites was proposed upon the discovery of a reduced non-photosynthetic plastid termed the apicoplast in their cells. Although it is clear that the apicoplast has evolved through a secondary endosymbiosis, its particular origin within the red or green plastid lineage remains controversial. The recent discovery of Chromera velia, the closest known photosynthetic relative to apicomplexan parasites, sheds new light on the evolutionary history of alveolate plastids. Here we review our knowledge on the evolutionary history of Apicomplexa and particularly their plastids, with a focus on the pathway by which they evolved from free-living heterotrophs through photoautotrophs to omnipresent obligatory intracellular parasites. New sequences from C. velia (histones H2A, H2B; GAPDH, TufA) and phylogenetic analyses are also presented and discussed here.     

The Plasmodium Apicoplast Genome: Conserved Structure and Close Relationship of P. ovale to Rodent Malaria Parasites

Apicoplast, a nonphotosynthetic plastid derived from secondary symbiotic origin, is essential for the survival of malaria parasites of the genus Plasmodium. Elucidation of the evolution of the apicoplast genome in Plasmodium species is important to better understand the functions of the organelle. However, the complete apicoplast genome is available for only the most virulent human malaria parasite, Plasmodium falciparum. Here, we obtained the near-complete apicoplast genome sequences from eight Plasmodium species that infect a wide variety of vertebrate hosts and performed structural and phylogenetic analyses. We found that gene repertoire, gene arrangement, and other structural attributes were highly conserved. Phylogenetic reconstruction using 30 protein-coding genes of the apicoplast genome inferred, for the first time, a close relationship between P. ovale and rodent parasites. This close relatedness was robustly supported using multiple evolutionary assumptions and models. The finding suggests that an ancestral host switch occurred between rodent and human Plasmodium parasites.     

Babesia bovis: A comprehensive phylogenetic analysis of plastid-encoded genes supports green algal origin of apicoplasts

Apicomplexan parasites commonly contain a unique, non-photosynthetic plastid-like organelle termed the apicoplast. Previous analyses of other plastid-containing organisms suggest that apicoplasts were derived from a red algal ancestor. In this report, we present an extensive phylogenetic study of apicoplast origins using multiple previously reported apicoplast sequences as well as several sequences recently reported. Phylogenetic analysis of amino acid sequences was used to determine the evolutionary origin of the organelle. A total of nine plastid genes from 37 species were incorporated in our study. The data strongly support a green algal origin for apicoplasts and Euglenozoan plastids. Further, the nearest green algae lineage to the Apicomplexans is the parasite Helicosporidium, suggesting that apicoplasts may have originated by lateral transfer from green algal parasite lineages. The results also substantiate earlier findings that plastids found in Heterokonts such as Odontella and Thalassiosira were derived from a separate secondary endosymbiotic event likely originating from a red algal lineage.     

New comprehension of the apicoplast of Sarcocystis by transmission electron tomography

BACKGROUND INFORMATION: Apicomplexan parasites (like Plasmodium, Toxoplasma, Eimeria and Sarcocystis) contain a distinctive organelle, the apicoplast, acquired by a secondary endosymbiotic process analogous to chloroplasts and mitochondria. The apicoplast is essential for long-term survival of the parasite. This prokaryotic origin implies that molecular and metabolic processes in the apicoplast differ from those of the eukaryotic host cells and therefore offer options for specific chemotherapeutic treatment. We studied the apicoplast in high-pressure frozen and freeze-substituted cysts of Sarcocystis sp. from roe deer (Capreolus capreolus) to get better insight in apicoplast morphology. RESULTS AND CONCLUSIONS: We observed that the apicoplast contains four continuous membranes. The two inner membranes have a circular shape with a constant distance from each other and large-sized protein complexes are located between them. The two outer membranes have irregular shapes. The periplastid membrane also contains large-sized protein complexes, while the outer membrane displays protuberances into the parasite cytoplasm. In addition, it is closely associated with the endoplasmic reticulum by 'contact sites'.     

Plasmodium falciparum OTU‐like cysteine protease (PfOTU) is essential for apicoplast homeostasis and associates with noncanonical role of Atg8

The metabolic pathways associated with the mitochondrion and the apicoplast in Plasmodium, 2 parasite organelles of prokaryotic origin, are considered as suitable drug targets. In the present study, we have identified functional role of a novel ovarian tumour unit (OTU) domain‐containing cysteine protease of Plasmodium falciparum (PfOTU). A C‐terminal regulatable fluorescent affinity tag on native protein was utilised for its localization and functional characterization. Detailed studies showed vesicular localization of PfOTU and its association with the apicoplast. Degradation‐tag mediated knockdown of PfOTU resulted in abnormal apicoplast development and blocked development of parasites beyond early‐schizont stages in subsequent cell cycle; downregulation of PfOTU hindered apicoplast protein import. Further, the isoprenoid precursor‐mediated parasite growth‐rescue experiments confirmed that PfOTU knockdown specifically effect development of functional apicoplast. We also provide evidence for a possible biological function of PfOTU in membrane deconjugation of Atg8, which may be linked with the apicoplast protein import. Overall, our results show that the PfOTU is involved in apicoplast homeostasis and associates with the noncanonical function of Atg8 in maintenance of parasite apicoplast.     

Protein trafficking to the plastid of Plasmodium falciparum is via the secretory pathway

The plastid of Plasmodium falciparum (or 'apicoplast') is the evolutionary homolog of the plant chloroplast and represents a vestige of a photosynthetic past. Apicoplast indispensability indicates that it still provides essential functions to parasites. Similar to plant chloroplasts, the apicoplast is dependent on many nucleus-encoded genes to provide these functions. The apicoplast is surrounded by four membranes, two more than plant chloroplasts. Thus, protein targeting to the apicoplast must overcome additional membrane barriers. In P.falciparum we have analyzed apicoplast targeting using green fluorescent protein (GFP). We demonstrate that protein targeting is at least a two-step process mediated by bipartite N-terminal pre-sequences that consist of a signal peptide for entry into the secretory pathway and a plant-like transit peptide for subsequent import into the apicoplast. The P.falciparum transit peptide is exceptional compared with other known plastid transit peptides in not requiring serine or threonine residues. The pre-sequence components are removed stepwise during apicoplast targeting. Targeting GFP to the apicoplast has also provided the first opportunity to examine apicoplast morphology in live P. falciparum.