昆虫共生细菌Rickettsia的研究进展

Rickettsia是传播和引起人类与其他脊椎动物疾病的胞内共生菌。引起脊椎动物疾病的这些Rickettsia, 其部分生活史是在节肢动物体内完成的;而另外许多Rickettsia, 其整个生活史都是在宿主节肢动物体内完成。为了叙述方便, 把前者称为脊椎动物Rickettsia, 后者称为节肢动物Rickettsia。过去的研究主要集中在医学上具有重大意义的脊椎动物Rickettsia, 而关于节肢动物Rickettsia的生物学特性等研究则相对较少。近年来, 研究者们加大了对昆虫Rickettsia的研究, 发现昆虫Rickettsia广泛分布于昆虫中, 且有两种存在形式。其可以通过垂直卵传的方式在世代间传递, 也可以通过寄生蜂和寄主植物达到在昆虫之间传播的目的。昆虫Rickettsia可通过诱导孤雌生殖、 诱导杀雄等方式影响宿主的生殖行为。其对不同宿主昆虫可产生对宿主有利或有害的作用;可增强宿主昆虫抵御高温和寄生蜂的能力, 与宿主昆虫对药剂的敏感性相关。最后, 昆虫Rickettsia具有一个简化的基因组, 且存在进一步减小的可能性。     

The emerging diversity of Rickettsia

The best-known members of the bacterial genus Rickettsia are associates of blood-feeding arthropods that are pathogenic when transmitted to vertebrates. These species include the agents of acute human disease such as typhus and Rocky Mountain spotted fever. However, many other Rickettsia have been uncovered in recent surveys of bacteria associated with arthropods and other invertebrates; the hosts of these bacteria have no relationship with vertebrates. It is therefore perhaps more appropriate to consider Rickettsia as symbionts that are transmitted vertically in invertebrates, and secondarily as pathogens of vertebrates. In this review, we highlight the emerging diversity of Rickettsia species that are not associated with vertebrate pathogenicity. Phylogenetic analysis suggests multiple transitions between symbionts that are transmitted strictly vertically and those that exhibit mixed (horizontal and vertical) transmission. Rickettsia may thus be an excellent model system in which to study the evolution of transmission pathways. We also focus on the emergence of Rickettsia as a diverse reproductive manipulator of arthropods, similar to the closely related Wolbachia, including strains associated with male-killing, parthenogenesis, and effects on fertility. We emphasize some outstanding questions and potential research directions, and suggest ways in which the study of non-pathogenic Rickettsia can advance our understanding of their disease-causing relatives.     

Biochemical and genetical study of Rickettsia

The review deals with the phenomenology in the studies on characteristics of surface antigenic and immunogenic structures of Rickettsia, their cellular membranes, the processes of metabolic cooperation and interaction with the host cells, and the structure of Rickettsia genome. The data on active antigenic and immunogenic proteins distribution in inner and outer membranes and on osmotically active functioning cellular membrane, including the specific substrate carriers, are discussed. The materials, are presented on the specific ADP-ATP transport system, slightly different from the mitochondrial one, in evidence that Rickettsia utilize ATP in two pathways: endogenous and exogenous. The metabolic regulatory processes, controlled by adenine nucleotides are discussed that could be used as a means of fitting to constantly changing conditions of Rickettsia ecological niche. The Rickettsia deficiency in AMP catabolism enzyme could be used for allosteric-regulation of citrate synthase, the key enzyme in the Krebs cycle. The data on the mol mass of Rickettsia DNA (1 x 10(9)) and the characteristics of plasmids are presented. In conclusion new data on molecular cloning of Rickettsia genes in vector plasmids and the restriction analysis of specific DNA sequences are discussed.     

Molecular phylogeny and rearrangement of rRNA genes in Rickettsia species.

It has previously been observed that Rickettsia prowazekii has an unusual arrangement of the rRNA genes. In this species, the three rRNA genes, 16S (rrs), 23S (rrl), and 5S (rrf), are not linked in the typical arrangements for bacteria. Rather, the 16S rRNA gene has been separated from the 23S and 5S rRNA gene cluster, and the 23S rRNA gene is preceded by a gene which codes for methionyl-tRNAf(Met) formyltransferase (fmt). In this study, we screened the genus Rickettsia for the fmt-rrl motif in order to examine the phylogenetic depth of this unusual rRNA gene organization. A rearranged operon structure was observed in Rickettsia conorii, Rickettsia parkeri, Rickettsia sibirica, Rickettsia rickettsii, Rickettsia amblyomii, Rickettsia montana, Rickettsia rhipicephali, Rickettsia australis, Rickettsia akari, Rickettsia felis, Rickettsia canada, and Rickettsia typhi. There is also evidence for a divided operon in Rickettsia belli, but in this species, the fmt gene could not be identified upstream of the 23S rRNA gene. In order to place the rearrangement event in the evolutionary history of the Rickettsia, phylogenetic analyses were performed based on the fmt-rrl spacer regions and the 23S rRNA genes. Based on these phylogenies, we suggest that the genomic rearrangement of the rRNA genes preceded the divergence of the typhus group and the spotted fever group Rickettsia. The unique organization of the 23S rRNA genes provides a simple diagnostic tool for identification of Rickettsia species.     

Some lessons from Rickettsia genomics

Sequencing of the Rickettsia conorii genome and its comparison with its closest sequenced pathogenic relative, i.e., Rickettsia prowazekii, provided powerful insights into the evolution of these microbial pathogens. However, advances in our knowledge of rickettsial diseases are still hindered by the difficulty of working with strict intracellular bacteria and their hosts. Information gained from comparing the genomes of closely related organisms will shed new light on proteins susceptible to be targeted in specific diagnostic assays, by new antimicrobial drugs, and that could be employed in the generation of future rickettsial vaccines. In this review we present a detailed comparison of the metabolic pathways of these bacteria as well as the polymorphisms of their membrane proteins, transporters and putative virulence factors. Environmental adaptation of Rickettsia is also discussed.     

Novel clade of Rickettsia spp. from leeches

Intracellular rickettsia-like structures were found in the tissues of a glossiphoniid leech, Torix tagoi, by transmission electron microscopy. Diagnostic PCR analysis using specific primers suggested that of the nine glossiphoniid species examined, two species, T. tagoi and Hemicrepsis marginata, harbored bacteria of the genus Rickettsia. A 1.5-kb eubacterial 16S rRNA gene segment obtained from each of these species was amplified by PCR, cloned, and sequenced. Phylogenetic analysis of the 16S rRNA gene demonstrated that the Rickettsia species found in the leeches constituted a novel clade that is distinct from the clade of arthropod-associated Rickettsia species. In natural populations, 97.7% (43 of 44) of T. tagoi leeches and 100% (9 of 9) of H. marginata leeches carried Rickettsia, suggesting that infection with Rickettsia is prevalent in these leeches. This is the first report of Rickettsia found in annelids.     

Genomic comparison of Rickettsia helvetica and other Rickettsia species

We report the complete and annotated genome sequence of Rickettsia helvetica strain C9P9, which was first isolated in 1979 from Ixodes ricinus ticks in Switzerland and is considered a human pathogen.     

Expression of an epitope-tagged virulence protein in Rickettsia parkeri using transposon insertion

Despite recent advances in our ability to genetically manipulate Rickettsia, little has been done to employ genetic tools to study the expression and localization of Rickettsia virulence proteins. Using a mariner-based Himar1 transposition system, we expressed an epitope-tagged variant of the actin polymerizing protein RickA under the control of its native promoter in Rickettsia parkeri, allowing the detection of RickA using commercially-available antibodies. Native RickA and epitope-tagged RickA exhibited similar levels of expression and were specifically localized to bacteria. To further facilitate protein expression in Rickettsia, we also developed a plasmid for Rickettsia insertion and expression (pRIE), containing a variant Himar1 transposon with enhanced flexibility for gene insertion, and used it to generate R. parkeri strains expressing diverse fluorescent proteins. Expression of epitope-tagged proteins in Rickettsia will expand our ability to assess the regulation and function of important virulence factors.     

Horizontal transmission of the insect symbiont Rickettsia is plant-mediated

Bacteria in the genus Rickettsia, best known as vertebrate pathogens vectored by blood-feeding arthropods, can also be found in phytophagous insects. The presence of closely related bacterial symbionts in evolutionarily distant arthropod hosts presupposes a means of horizontal transmission, but no mechanism for this transmission has been described. Using a combination of experiments with live insects, molecular analyses and microscopy, we found that Rickettsia were transferred from an insect host (the whitefly Bemisia tabaci) to a plant, moved inside the phloem, and could be acquired by other whiteflies. In one experiment, Rickettsia was transferred from the whitefly host to leaves of cotton, basil and black nightshade, where the bacteria were restricted to the phloem cells of the plant. In another experiment, Rickettsia-free adult whiteflies, physically segregated but sharing a cotton leaf with Rickettsia-plus individuals, acquired the Rickettsia at a high rate. Plants can serve as a reservoir for horizontal transmission of Rickettsia, a mechanism which may explain the occurrence of phylogenetically similar symbionts among unrelated phytophagous insect species. This plant-mediated transmission route may also exist in other insect-symbiont systems and, since symbionts may play a critical role in the ecology and evolution of their hosts, serve as an immediate and powerful tool for accelerated evolution.     

Sequence and annotation of Rickettsia sibirica sibirica genome

Rickettsia sibirica sibirica is the causative agent of Siberian or North Asian tick typhus, a tick-borne rickettsiosis known to exist in Siberia and eastern China. Here we present the draft genome of Rickettsia sibirica sibirica strain BJ-90 isolated from Dermacentor sinicus ticks collected in Beijing, China.     

Serologic survey of Eptesicus fuscus from Georgia, U.S.A. for Rickettsia and Borrelia and laboratory transmission of a Rickettsia by bat ticks.

Bats and their ectoparasites are associated with bacterial agents of unknown pathogenicity. We tested sera from 56 Eptesicus fuscus from Georgia against Borrelia hermsii, Orientia tsutsugamushi, Rickettsia conorii, and Rickettsia rickettsii. We detected antibodies reactive against a relapsing fever Borrelia and spotted fever group Rickettsia in 3/56 and 1/56 bats, respectively. We attempted to culture Bartonella from the blood of these bats but were unsuccessful. In addition, we fed bat ticks, Carios kelleyi, infected with Rickettsia on a specific pathogen-free guinea pig. The guinea pig had a weak seroconversion to R. rickettsii with a peak titer of 1:32 starting on day 14. Rickettsia was not detected in any of the tissue samples from the guinea pig by molecular means. Our results indicate that E. fuscus is naturally exposed to both a spotted fever group Rickettsia and a relapsing fever group Borrelia. If these agents are transmitted by bat ticks, then people living in close proximity to bat ticks might be exposed.     

黑龙江立克次体与黑龙江蜱传斑点热研究概况

黑龙江立克次体是近年发现的斑点热群立克次体新种,由其引起的疾病为黑龙江蜱传斑点热。综述了黑龙江立克次体的发现、分离鉴定、病原学和分子生物学特征,介绍了黑龙江蜱传斑点热的流行病学、临床表现及治疗与预防。     

Detection of spotted fever group Rickettsia in Haemaphysalis longicornis from Hebei Province, China

DNA samples from 737 tick pools, representing 6,850 Haemaphysalis longicornis and 51 Dermacentor nuttalli collected from Hebei Province, China, were analyzed by polymerase chain reaction (PCR) for the presence of spotted fever group Rickettsia. Fifty (6.9%) of 724 H. longicornis in the tick pool were positive, but no positive samples were found in 13 D. nuttalli. Sequence analysis of the partial outer membrane protein A (ompA) genes from the 10 positive samples showed 97.4-99.8% identity, but were different from the homologous sequence of Rickettsia previously deposited in GenBank. Phylogenetic analysis of ompA genes indicated that the Rickettsia detected in this study belonged to a novel haplotype, and formed a clade distinct from Rickettsia heilongjiangii, Rickettsia sibirica, and Rickettsia hulinii in China. The new strain, named Candidatus Rickettsia hebeiii, appears to represent a distinct lineage and could constitute a new species with a minimum prevalence of about 0.7% in H. longicornis from Hebei Province, China.     

Genome degradation is an ongoing process in Rickettsia.

To study reductive evolutionary processes in bacterial genomes, we examine sequences in the Rickettsia genomes which are unconstrained by selection and evolve as pseudogenes, one of which is the metK gene, which codes for AdoMet synthetase. Here, we sequenced the metK gene and three surrounding genes in eight different species of the genus Rickettsia. The metK gene was found to contain a high incidence of deletions in six lineages, while the three genes in its surroundings were functionally conserved in all eight lineages. A more drastic example of gene degradation was identified in the metK downstream region, which contained an open reading frame in Rickettsia felis. Remnants of this open reading frame could be reconstructed in five additional species by eliminating sites of frameshift mutations and termination codons. A detailed examination of the two reconstructed genes revealed that deletions strongly predominate over insertions and that there is a strong transition bias for point mutations which is coupled to an excess of GC-to-AT substitutions. Since the molecular evolution of these inactive genes should reflect the rates and patterns of neutral mutations, our results strongly suggest that there is a high spontaneous rate of deletions as well as a strong mutation bias toward AT pairs in the Rickettsia genomes. This may explain the low genomic G + C content (29%), the small genome size (1.1 Mb), and the high noncoding content (24%), as well as the presence of several pseudogenes in the Rickettsia prowazekii genome.     

First detection of Rickettsia in soft-bodied ticks associated with seabirds, Japan

Rickettsia was first detected in seabird soft-bodied ticks, Carios capensis and C. sawaii in Japan. According to sequence analysis, Rickettsia in Japan was identical to Rickettsia scc31 in C. capensis in the U.S.A. This suggested that an environmental circulation had consisted among microorganisms, ticks and long distance migratory seabirds around the Pacific Ocean.     

Development of shuttle vectors for transformation of diverse Rickettsia species

Plasmids have been identified in most species of Rickettsia examined, with some species maintaining multiple different plasmids. Three distinct plasmids were demonstrated in Rickettsia amblyommii AaR/SC by Southern analysis using plasmid specific probes. Copy numbers of pRAM18, pRAM23 and pRAM32 per chromosome in AaR/SC were estimated by real-time PCR to be 2.0, 1.9 and 1.3 respectively. Cloning and sequencing of R. amblyommii AaR/SC plasmids provided an opportunity to develop shuttle vectors for transformation of rickettsiae. A selection cassette encoding rifampin resistance and a fluorescent marker was inserted into pRAM18 yielding a 27.6 kbp recombinant plasmid, pRAM18/Rif/GFPuv. Electroporation of Rickettsia parkeri and Rickettsia bellii with pRAM18/Rif/GFPuv yielded GFPuv-expressing rickettsiae within 2 weeks. Smaller vectors, pRAM18dRG, pRAM18dRGA and pRAM32dRGA each bearing the same selection cassette, were made by moving the parA and dnaA-like genes from pRAM18 or pRAM32 into a vector backbone. R. bellii maintained the highest numbers of pRAM18dRGA (13.3 - 28.1 copies), and R. parkeri, Rickettsia monacensis and Rickettsia montanensis contained 9.9, 5.5 and 7.5 copies respectively. The same species transformed with pRAM32dRGA maintained 2.6, 2.5, 3.2 and 3.6 copies. pRM, the plasmid native to R. monacensis, was still present in shuttle vector transformed R. monacensis at a level similar to that found in wild type R. monacensis after 15 subcultures. Stable transformation of diverse rickettsiae was achieved with a shuttle vector system based on R. amblyommii plasmids pRAM18 and pRAM32, providing a new research tool that will greatly facilitate genetic and biological studies of rickettsiae.     

Transovarial transmission of Rickettsia spp. and organ-specific infection of the whitefly Bemisia tabaci

The whitefly Bemisia tabaci is a cosmopolitan insect pest that harbors Portiera aleyrodidarum, the primary obligatory symbiotic bacterium, and several facultative secondary symbionts. Secondary symbionts in B. tabaci are generally associated with the bacteriome, ensuring their vertical transmission; however, Rickettsia is an exception and occupies most of the body cavity, except the bacteriome. The mode of Rickettsia transfer between generations and its subcellular localization in insect organs have not been investigated. Using electron and fluorescence microscopy, we show that Rickettsia infects the digestive, salivary, and reproductive organs of the insect; however, it was not observed in the bacteriome. Rickettsia invades the oocytes during early developmental stages and resides in follicular cells and cytoplasm; it is mostly excluded when the egg matures; however, some bacterial cells remain in the egg, ensuring their transfer to subsequent generations. Rickettsia was localized to testicles and the spermatheca, suggesting a horizontal transfer between males and females during mating. The bacterium was further observed at large amounts in midgut cells, concentrating in vacuole-like structures, and was located in the hemolymph, specifically at exceptionally large amounts around bacteriocytes and in fat bodies. Organs further infected by Rickettsia included the primary salivary glands and stylets, sites of possible secretion of the bacterium outside the whitefly body. The close association between Rickettsia and the B. tabaci digestive system might be important for digestive purposes. The vertical transmission of Rickettsia to subsequent generations occurs via the oocyte and not, like other secondary symbionts, the bacteriome.     

The library of Rickettsia prowazekii genes

The DNA of Rickettsia provazekii strain E was cleaved by PstI restriction endonuclease under the conditions of partial restriction. The fragments were inserted into the PstI site of pBR325 and cloned in this plasmid. E. coli strain HB101 was used as a recipient for cloning. 880 clones sensitive to ampicillin and resistant to tetracycline were selected from 5120 transformants. The cloning of rickettsial DNA has been confirmed by the blot hybridization technique. Analysis of individual and net probes of the hybrid DNA by gel electrophoresis makes it possible to conclude that 90% of the selected clones harbour hybrid plasmids, the size of the cloned fragments rangers from 0.9 to 10.4 Kb, the obtained library of clones contains 70% of the whole genome of Rickettsia provazekii.     

Genome sequence of "Rickettsia sibirica subsp. mongolitimonae"

"Rickettsia sibirica subsp. mongolitimonae" is the agent of lymphangitis-associated rickettsiosis, an emerging human disease that has been diagnosed in Europe and Africa. The present study reports the draft genome of Rickettsia sibirica subsp. mongolitimonae strain HA-91.     

Serosurvey of Rickettsia typhi and Rickettsia felis in HIV‐infected patients

Consistent with the effects of HIV on cell‐mediated immunity, an increased susceptibility to intracellular microorganisms has been observed. Rickettsiae are obligate intracellular microorganisms. The aim of this study was to examine Rickettsia typhi and Rickettsia felis infections in HIV+ population. Sera of 341 HIV+ patients were evaluated by indirect immunofluorescent assay. Age, sex, residential locality, risk behavior, stage according to criteria of the Center for Disease Control and Prevention, CD4+/CD8+ T cells, Hepatitis B antigen, and Hepatitis C serology were surveyed. Seroprevalences of R. typhi and R. felis infection were 7.6% and 4.4%, respectively. No associations were found between seropositivities and the assessed variables. Findings were similar to those obtained in healthy subjects from the same region.