Classification of Brucella spp. isolated from marine mammals by DNA polymorphism at the omp2 locus

A number of recent reports have described the isolation and characterization of Brucella strains from a wide variety of marine mammals such as seals, porpoises, dolphins and a minke whale. These strains were identified as brucellae by conventional typing tests. However, their overall characteristics were not assimilable to those of any of the six currently recognized Brucella species and it was suggested that they comprise a new nomen species to be called Brucella maris. In the present study we analysed DNA polymorphism at the omp2 locus of 33 marine mammal Brucella strains isolated from seals, dolphins, porpoises and an otter. The omp2 locus contains two gene copies (named omp2a and omp2b) coding for porin proteins and has been found particularly useful for molecular typing and identification of Brucella at the species, biovar, or strain level. PCR-restriction fragment length polymorphism (RFLP) and DNA sequencing showed that strains isolated from dolphins and porpoises carry two omp2b gene copies instead of one omp2a and one omp2b gene copy or two similar omp2a gene copies reported in the currently recognized species. This observation was also recently made for a minke whale Brucella isolate. The otter and all seal isolates except one were shown to carry one omp2a and one omp2b gene copy as encountered in isolates from terrestrial mammals. By PCR-RFLP of the omp2b gene, a specific marker was detected grouping the marine mammal Brucella isolates. Although marine mammal Brucella isolates may represent a separate group from terrestrial mammal isolates based on omp2b sequence constructed phylogenetic trees, the divergence found between their omp2b and also between their omp2a nucleotide sequences indicates that they form a more heterogeneous group than isolates from terrestrial mammals. Therefore, grouping the marine mammal Brucella isolates into one species Brucella maris seems inappropriate unless the currently recognized Brucella species are grouped. With respect to the current classification of brucellae according to the preferential host, brucellae isolated from such diverse marine mammal species as seals and dolphins could actually comprise more than one species, and at least two new species, B. pinnipediae and B. cetaceae, could be compatible with the classical criteria of host preferentialism and DNA polymorphism at their omp2 locus.     

Incidence of Brucella species in marine mammals of the German North Sea

In this study, organ samples from 426 common seals Phoca vitulina, 298 harbour porpoises Phocoena phocoena, 34 grey seals Halichoerus grypus and 10 other marine mammals were assessed for the presence of Brucella species. Forty-seven common seals, 2 harbour porpoises and 1 grey seal were found to be positive for these bacteria. A total of 91 Brucella strains were successfully isolated, due to the fact that Brucella spp. were found in more than one organ sample in 15 animals. The primary organ in which the bacteria were present was the lung. In addition, 2 strains were isolated from lungworms (Parafilaroides spp.). Forty-nine of the isolated strains were selected for further analysis using conventional phenotyping methods. Molecular characterisation was carried out by analysing the IS711 and omp2 loci. With respect to the distribution of the IS711 loci in the genome, the 49 field isolates differed strongly from the terrestrial Brucella species and marginally from the marine Brucella reference strain NCTC12890. Based on the results of the PCR restriction fragment length polymorphism (PCR-RFLP) investigation of the omp2 locus, the majority of the Brucella field isolates were classified as B. pinnipediae, recently proposed B. pinnipedialis, possessing 1 omp2a gene and 1 omp2b gene. Two field isolates revealed the presence of 2 omp2a genes, as has been described for Brucella ovis. To our knowledge, these results confirm for the first time the presence of Brucella species in the marine mammal population of the German North Sea. These findings highlight the need for additional research on the relevance of these Brucella species for marine hosts and their environment.     

Chimeric structure of omp2 of Brucella from Pacific common minke whales (Balaenoptera acutorostrata)

In the Pacific common minke whale (Balaenoptera acutorostrata ), a new variant of Brucella has been detected using the polymerase chain reaction. Detailed analysis of the porin protein genes, omp2a and omp2b from the whale Brucella showed that these two genes have some motifs in common with Atlantic marine strains in the 5'-terminal one-third region. On the other hand, the nucleotide sequences in the 3'-terminal two-thirds region of the two genes were almost identical to the respective genes of terrestrial strains. Thus, Pacific whale Brucella omp2 genes are chimeras between marine and terrestrial strains.     

Genetic variation at the omp2 porin locus of the brucellae: species-specific markers

The omp2 locus of Brucella abortus is composed of two closely related genes (omp2a and omp2b) that encode, and potentially both express, homologous porin proteins. Genetic variation at this locus is revealed in the form of restriction-fragment-length polymorphisms which can be used to distinguish the type strains of all six Brucella species. Five of the six species contain single copies of omp2a and omp2b, whereas Brucella ovis appears to have two copies of the omp2a gene. The implications of these results with regard to the physiological functions of the omp2a and the omp2b gene products, phylogeny of the genus, and species-specific adaptation are discussed.     

Intraspecies biodiversity of the genetically homologous species Brucella microti

Brucellosis is one of the major bacterial zoonoses worldwide. In the past decade, an increasing number of atypical Brucella strains and species have been described. Brucella microti in particular has attracted attention, because this species not only infects mammalian hosts but also persists in soil. An environmental reservoir may pose a new public health risk, leading to the reemergence of brucellosis. In a polyphasic approach, comprising conventional microbiological techniques and extensive biochemical and molecular techniques, all currently available Brucella microti strains were characterized. While differing in their natural habitats and host preferences, B. microti isolates were found to possess identical 16S rRNA, recA, omp2a, and omp2b gene sequences and identical multilocus sequence analysis (MLSA) profiles at 21 different genomic loci. Only highly variable microsatellite markers of multiple-locus variable-number tandem repeat (VNTR) analysis comprising 16 loci (MLVA-16) showed intraspecies discriminatory power. In contrast, biotyping demonstrated striking differences within the genetically homologous species. The majority of the mammalian isolates agglutinated only with monospecific anti-M serum, whereas soil isolates agglutinated with anti-A, anti-M, and anti-R sera. Bacteria isolated from animal sources were lysed by phages F1, F25, Tb, BK2, Iz, and Wb, whereas soil isolates usually were not. Rough strains of environmental origin were lysed only by phage R/C. B. microti exhibited high metabolic activities similar to those of closely related soil organisms, such as Ochrobactrum spp. Each strain was tested with 93 different substrates and showed an individual metabolic profile. In summary, the adaptation of Brucella microti to a specific habitat or host seems to be a matter of gene regulation rather than a matter of gene configuration.     

Classification of Brucella strains isolated from marine mammals by infrequent restriction site-PCR and development of specific PCR identification tests

Brucella strains have been isolated since the 1990s from a wide variety of marine mammals and represent potential zoonotic pathogens. They have distinctive phenotypic and molecular characteristics from the terrestrial mammal Brucella species, and two new species names have been previously proposed based on DNA polymorphism at the omp2 locus and their preferential host, i.e. Brucella cetaceae for cetacean isolates and Brucella pinnipediae for pinniped isolates. The results presented in this study on characterization of these strains by infrequent restriction site-PCR (IRS-PCR), taking into account the higher number of IS711 elements in their genome compared to terrestrial mammal Brucella species, supports this classification. The nucleotide sequences of specific DNA fragments detected by IRS-PCR were determined and used to develop PCR identification tests for either B. cetaceae or B. pinnipediae.     

Genetic Polymorphism Characteristics of Brucella canis Isolated in China

In China, brucellosis is an endemic disease typically caused by Brucella melitensis infection (biovars 1 and 3). Brucella canis infection in dogs has not traditionally recognized as a major problem. In recent years however, brucellosis resulting from Brucella canis infection has also been reported, suggesting that infections from this species may be increasing. Data concerning the epidemiology of brucellosis resulting from Brucella canis infection is limited. Therefore, the purpose of this study was to assess the diversity among Chinese Brucella canis strains for epidemiological purposes. First, we employed a 16-marker VNTR assay (Brucella MLVA-16) to assess the diversity and epidemiological relationship of 29 Brucella canis isolates from diverse locations throughout China with 38 isolates from other countries. MLVA-16 analysis separated the 67 Brucella canis isolates into 57 genotypes that grouped into five clusters with genetic similarity coefficients ranging from 67.73 to 100%. Moreover, this analysis revealed a new genotype (2-3-9-11-3-1-5-1:118), which was present in two isolates recovered from Guangxi in 1986 and 1987. Second, multiplex PCR and sequencing analysis were used to determine whether the 29 Chinese Brucella canis isolates had the characteristic BMEI1435 gene deletion. Only two isolates had this deletion. Third, amplification of the omp25 gene revealed that 26 isolates from China had a T545C mutation. Collectively, this study reveals that considerable diversity exists among Brucella canis isolates in China and provides resources for studying the genetic variation and microevolution of Brucella.     

DNA polymorphism in the omp25/omp31 family of Brucella spp.: identification of a 1.7-kb inversion in Brucella cetaceae and of a 15.1-kb genomic island, absent from Brucella ovis, related to the synthesis of smooth lipopolysaccharide

Five genes homologous to the well-known omp25 and omp31 genes, that code for two major Brucella spp. outer membrane proteins (OMPs), have been detected in the genome of Brucella melitensis 16M and Brucella suis 1330. In this work we have determined the nucleotide sequence of these five genes, named omp31b, omp25b, omp25c, omp25d and omp22, in the six classical Brucella species reference strains and in representative strains of the recently proposed species Brucella cetaceae and Brucella pinnipediae that classify the Brucella strains isolated in the last years from marine mammals. Although these genes are quite conserved in the genus Brucella, several important differences have been found between species (i) omp31b contains a premature stop codon in B. canis and B. ovis truncating the encoded protein; (ii) the 5' end of omp31b is deleted in the three biovars of B. melitensis which probably prevents synthesis of Omp31b in this species; (iii) only B. melitensis, B. suis and B. neotomae would be able to synthesize the Omp25b protein with the characteristics shared by the Omp25/Omp31 group of proteins (characteristic signal sequence and C-terminal phenylalanine); (iv) a DNA inversion of 1747 bp including omp25b was detected in B. cetaceae strains; (v) a DNA deletion of about 15 kb was detected in all the six B. ovis strains tested. This deletion in B. ovis includes, among other genes, omp25b and wboA, a gene that has been shown to be required for the synthesis of the O-polysaccharide chain of the Brucella spp. smooth lipopolysaccharide. Several features of the DNA region absent from B. ovis suggest that this DNA fragment is a genomic island acquired by the Brucella ancestor by horizontal transfer and later deleted from B. ovis. The DNA polymorphism we have found in this work within the genus Brucella might be involved in the differences in pathogenicity and host preference displayed by the Brucella species.     

Molecular evidence of new variant Brucella in North Pacific common minke whales

Brucella, a causative agent of brucellosis, has been isolated recently from a variety of marine mammals. The molecular analysis of marine mammalian Brucella strains, without manifest pathology of brucellosis in the eastern North Atlantic, showed that they are distinct from terrestrial Brucella species. Previously, we reported abnormal gonads in common minke whales (Balaenoptera acutorostrata) in the western North Pacific and suggested the presence of Brucella infection in the whales in pathology and serology studies. In the present study, using polymerase chain reaction (PCR), Brucella was detected in granular testes of the whales showing caseation or calcification. The insertion of an IS711 transposable element specific for marine mammal isolates as well as a seal isolate-specific DNA fragment were also found. Molecular characterization of Brucella based on sequence analysis of the PCR products amplified from the outer membrane protein (omp) 2 gene showed that the Brucella from North Pacific common minke whales was different from terrestrial and North Atlantic marine mammal Brucella strains. The North Pacific Brucella showed the highest similarity to North Atlantic seal strains among the known Brucella strains.     

Brucella Omp2a and Omp2b porins: single channel measurements and topology prediction

Brucella usually carry two highly homologous genes (omp2a and omp2b) for porin-like proteins. In several B. abortus biovars the omp2a gene has a large deletion compared to other Brucella omp2's. In this study we have measured Omp2 pore activity in planar bilayers. Omp2b exhibits well-defined trimeric channel activity whilst Omp2a forms monomeric pores of variable size which are smaller than Omp2b. No sequence homology exists between Omp2 and porins of known structure, so hydrophobic moment analysis has been used to model their membrane topology. From this it appears likely that the deletion removes the crucial L3 internal loop.     

Restriction site polymorphisms in the genes encoding new members of group 3 outer membrane protein family of Brucella spp

Thirty-seven Brucella reference and field strains representing all the species and their biovars were analysed by PCR-RFLP to determine the degree of variation in the genes encoding the new members of group 3 outer membrane protein (Omp) family. Analysis of the omp22 and omp25c/omp25d genes indicated that the restriction patterns were identical for all species and biovars with all restriction enzymes tested, except for Brucella ovis that showed a short 30 bp deletion close to omp22 gene, and for B. abortus biovar 6 and B. ovis that lacked a DdeI site and a HinfI site, respectively, in the omp25c/omp25d genes. Analysis of PCR products of the omp31b gene digested with 20 restriction enzymes revealed that this gene has a greater level of DNA polymorphism than the other genes encoding the new members of group 3 Omp family. A deletion of 232bp was detected in fourteen B melitensis strains from different hosts and from different geographic origins, confirming that this feature is indeed a hallmark of B. melitensis. PCR-RFLP analysis of omp31b with DdeI allowed us to identify species-specific markers for B. abortus, B. melitensis, and B. ovis. Finally, by PCR analysis, Southern blot hybridization and DNA sequencing we showed that a large deletion of 15 kb, comprising the entire omp25b gene and 21 more genes, is present in all B. ovis strains, thus confirming previous observations from other authors.     

Construction of an expression plasmid (vector) encoding Brucella melitensis outer membrane protein,a candidate for DNA vaccine

Background:

DNA vaccination with plasmid encoding bacterial, viral, and parasitic immunogens has been shown to be an attractive method to induce efficient immune responses. Bacteria of the genus Brucella are facultative intracellular pathogens for which new and efficient vaccines are needed.

Methods:

To evaluate the use of a DNA immunization strategy for protection against brucellosis, a plasmid containing the DNA encoding the Brucella melitensis (B. melitensis) 31 kDa outer membrane protein, as a potent immunogenic target, was constructed.

Results:

The constructed plasmid, pcDNA3.1+omp31, was injected intramuscularly into mice and the expression of omp31 RNA was assessed by RT-PCR. The integrity of the pcDNA3.1+omp31 construct was confirmed with restriction analysis and sequencing. Omp31 mRNA expression was verified by RT-PCR.

Conclusion:

Our results indicate that the pcDNA3.1+omp31 eukaryotic expression vector expresses omp31 mRNA and could be useful as a vaccine candidate.Key Words: Brucella melitensis, omp31, DNA Vaccine, pcDNA3.1     

Molecular genetic characterization of avian Chlamydophila psittaci isolates

Restriction enzyme analysis of the omp1 gene was used to characterize 51 avian Chlamydophila psittaci isolates. The analysis confirmed the predominance of genotype A in parrot C. psittaci isolates and revealed new omp1 genotypes in corvid C. psittaci isolates. The corvid isolates proved to lack an extrachromosomal plasmid. The omp1 and rRNA IGS sequences were determined for the new isolates. Phylogenetic analysis showed that isolate 1V, obtained from a crow, is intermediate in several characters between C. abortus and C. psittaci. The results were compared with data on the phylogenetic relationships of earlier chlamydium isolates.     

pUC19K质粒的构建及其在布鲁氏菌突变株构建中的应用

突变株的构建是细菌基因功能研究的前提。本研究构建了一个可用于布鲁氏菌突变株构建的自杀质粒。在pUC19质粒的多克隆位点插入卡那霉素抗性基因,在该基因两侧添加多个酶切位点,构建成为pUC19K。利用该质粒,我们构建了布鲁氏菌外膜蛋白Omp25基因的突变株。结果表明,利用该自杀质粒,通过一轮筛选即可得到目标基因被抗性基因替换的突变株。pUC19K质粒的构建及成功应用,为布鲁氏菌突变株的构建提供了一个快速有效的手段,也为布鲁氏菌的基因功能研究奠定了基础。     

DNA polymorphism in the genus Brucella

The genus Brucella has been described as consisting of six species, three of them including several biovars, which display a high degree of DNA homology by DNA-DNA hybridization. However, DNA polymorphism able to differentiate the six Brucella species and some of their biovars has been shown to exist. This work reviews the DNA variability in the genus Brucella and discusses the relationships between its members according to this genetic variability and a proposal for their evolution based on genetic diversity of the omp2 locus.     

Molecular genetic characterization of avian <Emphasis Type="Italic">Chlamydophila psittaci</Emphasis> isolates

RFLP analysis of the omp1 gene was used to characterize 51 avian Chlamydophila psittaci isolates. The analysis confirmed the predominance of genotype A in parrot C. psittaci isolates and revealed new omp1 genotypes in corvid C. psittaci isolates. The corvid isolates proved to lack an extrachromosomal plasmid. The omp1 and rRNA IGS sequences were determined for the new isolates. Phylogenetic analysis showed that isolate 1V, obtained from a crow, is intermediate in several characters between C. abortus and C. psittaci. The results were compared with data on the phylogenetic relationships of earlier chlamydium isolates.     

Establishment of loop-mediated isothermal amplification (LAMP) for rapid detection of Brucella spp. and application to milk and blood samples

Brucella spp. are facultative intracellular bacteria that infect humans and animals. In this study, the loop-mediated isothermal amplification (LAMP) was used to detect the Brucella-specific gene omp25. Reaction conditions were optimized as temperature 65°C, reaction time 60 min, Mg(2+) concentration 8.0 mmol/L, polymerase content Bst DNA, 0.5 μL, deoxyribonucleotide concentration 1.6 mmol/L, and inner/outer primer ratio 1:8. The LAMP method was evaluated with 4 Brucella species and 29 non-Brucella bacteria species. Positive reactions were observed on all the 4 Brucella species but not on any non-Brucella species. The limit of detection of the LAMP method was 3.81 CFU Brucella spp. Using the LAMP method, 7 of 110 raw milk samples and 5 of 59 sheep blood samples were detected positive of Brucella spp. Results indicated that LAMP is a fast, specific, sensitive, inexpensive, and suitable method for diagnosis of Brucella spp. infection.     

Cloning and sequencing of 28 kDa outer membrane protein gene of Brucella melitensis Rev. 1

Brucella melitensis is an organism of paramount zoonotic importance. The 28 kDa outer membrane protein (OMP) is one of the immunodominant antigens of B. melitensis. The gene encoding 28 kDa OMP (omp28) has been amplified from B. melitensis Rev. 1 strain. A PCR product of 753 bp, encoding complete omp28 gene of B. melitensis, was obtained. The gene was further cloned and sequenced. The nucleotide sequence of B. melitensis Rev. 1 strain showed substitution of 2 nucleotides from that of 16M strain.     

Analysis of membrane protein genes in a Brazilian isolate of Anaplasma marginale

The sequencing of the complete genome of Anaplasma marginale has enabled the identification of several genes that encode membrane proteins, thereby increasing the chances of identifying candidate immunogens. Little is known regarding the genetic variability of genes that encode membrane proteins in A. marginale isolates. The aim of the present study was to determine the degree of conservation of the predicted amino acid sequences of OMP1, OMP4, OMP5, OMP7, OMP8, OMP10, OMP14, OMP15, SODb, OPAG1, OPAG3, VirB3, VirB9-1, PepA, EF-Tu and AM854 proteins in a Brazilian isolate of A. marginale compared to other isolates. Hence, primers were used to amplify these genes: omp1, omp4, omp5, omp7, omp8, omp10, omp14, omp15, sodb, opag1, opag3, virb3, VirB9-1, pepA, ef-tu and am854. After polimerase chain reaction amplification, the products were cloned and sequenced using the Sanger method and the predicted amino acid sequence were multi-aligned using the CLUSTALW and MEGA 4 programs, comparing the predicted sequences between the Brazilian, Saint Maries, Florida and A. marginale centrale isolates. With the exception of outer membrane protein (OMP) 7, all proteins exhibited 92-100% homology to the other A. marginale isolates. However, only OMP1, OMP5, EF-Tu, VirB3, SODb and VirB9-1 were selected as potential immunogens capable of promoting cross-protection between isolates due to the high degree of homology (over 72%) also found with A. (centrale) marginale.     

Comparison of PCR-RFLP and PFGE for determining the clonality of Brucella isolates from human and livestock specimens

Brucellosis is an important zoonotic disease caused by different species of genus Brucella that are pathogenic for humans and a variety of animals. Accurate detection of Brucella spp. infection is important for control of disease. The aim of this study was to comparison of molecular genotyping of Brucella strains by Pulsed-field gel electrophoresis (PFGE) and polymerase chain reaction -Restriction Fragment Length Polymorphism (PCR-RFLP) techniques.Twenty- seven Brucella spp. were isolated from human and animal samples. The isolates identified by conventional microbiological methods and confirmed using PCR for amplification of omp2a gene. Molecular typing of Brucella strains carried out by PCR-RFLP after PstI and PFGE of chromosomal DNA after XbaI enzyme digestion. The omp2a gene PCR Products with different patterns of PCR-RFLP were sequenced.The omp2a gene amplification of all human and animal Brucella isolates were positive for 1100 bp fragment. By PCR-RFLP analysis two genotypes/patterns for human isolates and four genotypes for animal isolates were obtained. In PFGE analysis totally, 7 common clones/clusters and 3 single clones were obtained.The results of this study showed the PFGE method is the more reliable and useful assay for molecular typing of Brucella strains and is more preferred to PCR-RFLP in determination of genetic similarity among human and animal Brucella isolates. The presented data showed PCR-RFLP analysis was not able to differentiate between B. melitensis biovars and vaccine strain.