High Prevalence of Tropheryma whipplei in Lao Kindergarten Children

Background

Tropheryma whipplei is a bacterium commonly found in feces of young children in Africa, but with no data from Asia. We estimated the prevalence of T. whipplei carriage in feces of children in Lao PDR (Laos).

Methods/Principal Findings

Using specific quantitative real-time PCR, followed by genotyping for each positive specimen, we estimated the prevalence of T. whipplei in 113 feces from 106 children in Vientiane, the Lao PDR (Laos). T. whipplei was detected in 48% (51/106) of children. Those aged ≤4 years were significantly less frequently positive (17/52, 33%) than older children (34/54, 63%; p< 0.001). Positive samples were genotyped. Eight genotypes were detected including 7 specific to Laos. Genotype 2, previously detected in Europe, was circulating (21% of positive children) in 2 kindergartens (Chompet and Akad). Genotypes 136 and 138 were specific to Chompet (21% and 15.8%, respectively) whereas genotype 139 was specific to Akad (10.55%).

Conclusions/Significance

T. whipplei is a widely distributed bacterium, highly prevalent in feces of healthy children in Laos. Further research is needed to identify the public health significance of this finding.     

Tropheryma whipplei: a common bacterium in rural Senegal

Background

Tropheryma whipplei is known as the cause of Whipple''s disease, but it is also an emerging pathogen, detected in stool, that causes various chronic localized infections without histological digestive involvement and is associated with acute infections, including gastroenteritis and bacteremia.

Methods/Principal Findings

We conducted a study in 2008 and 2009 using 497 non-diarrheic and diarrheic stool samples, 370 saliva samples, 454 sera samples and 105 samples obtained from water samples in two rural Sine-Saloum villages (Dielmo and Ndiop) in Senegal. The presence of T. whipplei was investigated by using specific quantitative PCR. Genotyping was performed on positive samples. A serological analysis by western blotting was performed to determine the seroprevalence and to detect seroconversion. Overall, T. whipplei was identified in 31.2% of the stool samples (139/446) and 3.5% of the saliva samples (13/370) obtained from healthy subjects. The carriage in the stool specimens was significantly (p<10⁻³) higher in children who were between 0 and 4 years old (60/80, 75%) compared to samples obtained from individuals who were between 5 to 10 years old (36/119, 30.2%) or between 11 and 99 years old (43/247, 17.4%). The carriage in the stool was also significantly more common (p = 0.015) in subjects with diarrhea (25/51, 49%). We identified 22 genotypes, 16 of which were new. Only one genotype (#53) was common to both villages. Among the specific genotypes, one (#52) was epidemic in Dielmo (15/28, 53.4%, p<10⁻³) and another (#49) in Ndiop (27.6%, p = 0.002). The overall seroprevalence was estimated at 72.8% (291/400). Seroconversion was detected in 66.7% (18/27) of children for whom PCR became positive in stools between 2008 and 2009.

Conclusions/Significance

T. whipplei is a common bacterium in the Sine-Saloum area of rural Senegal that is contracted early in childhood. Epidemic genotypes suggest a human transmission of the bacterium.     

Global proteomic pattern of Tropheryma whipplei: A Whipple's disease bacterium

The proteome of Tropheryma whipplei, the intracellular bacterium responsible for Whipple's disease (WD), was analyzed using two complementary approaches: 2‐DE coupled with MALDI‐TOF and SDS‐PAGE with nanoLC‐MS/MS. This strategy led to the identification of 206 proteins of 808 predicted ORFs, resolving some questions raised by the genomic sequence of this bacterium. We successfully identified antibiotic targets and proteins with predicted N‐terminal signal sequences. Additionally, we identified a family of surface proteins (known as T. whipplei surface proteins (WiSPs)), which are encoded by a unique group of species‐specific genes and serve as both coding regions and DNA repeats that promote genomic recombination. Comparison of the protein expression profiles of the intracellular facultative host‐associated WD bacterium with other host‐associated, intracellular obligate, and environmental bacteria revealed that T. whipplei shares a proteomic expression profile with other host‐associated facultative intracellular bacteria. In summary, this study describes the global protein expression pattern of T. whipplei and reveals some specific features of the T. whipplei proteome.     

New insights into Whipple’s disease and Tropheryma whipplei infections

Whipple’s disease is a rare multi-systemic disease associated with the ubiquitous environmental bacterium Tropheryma whipplei. Over the last 10 years, since the isolation of the bacterium, recent advances in medical microbiology, epidemiology and cellular biology have provided major insights into the understanding of the pathophysiology of T. whipplei infections that may result in Whipple’s disease.     

IL-16 is critical for Tropheryma whipplei replication in Whipple's disease

Whipple's disease (WD) is a rare systemic disease caused by Tropheryma whipplei. We showed that T. whipplei was eliminated by human monocytes but replicated in monocyte-derived macrophages (Mphi) by inducing an original activation program. Two different host molecules were found to be key elements for this specific pattern. Thioredoxin, through its overexpression in infected monocytes, was involved in bacterial killing because adding thioredoxin to infected Mphi inhibited bacterial replication. IL-16, which was up-regulated in Mphi, enabled T. whipplei to replicate in monocytes and increased bacterial replication in Mphi. In addition, anti-IL-16 Abs abolished T. whipplei replication in Mphi. IL-16 down-modulated the expression of thioredoxin and up-regulated that of IL-16 and proapoptotic genes. In patients with WD, T. whipplei replication was higher than in healthy subjects and was related to high levels of circulating IL-16. Both events were corrected in patients who successfully responded to antibiotics treatment. This role of IL-16 was not reported previously and gives an insight into the understanding of WD pathophysiology.     

Tropheryma whipplei in the environment: survey of sewage plant influxes and sewage plant workers

We studied the prevalence of Tropheryma whipplei in influxes to 46 sewage treatment plants and in stool, mouthwash fluids, and dental plaques of 64 healthy workers in those facilities and 146 disease control patients. T. whipplei was found in sewage water, in stool of healthy individuals, and significantly more often in stool of workers exposed to sewage water.     

Tropheryma whipplei in the Environment: Survey of Sewage Plant Influxes and Sewage Plant Workers

We studied the prevalence of Tropheryma whipplei in influxes to 46 sewage treatment plants and in stool, mouthwash fluids, and dental plaques of 64 healthy workers in those facilities and 146 disease control patients. T. whipplei was found in sewage water, in stool of healthy individuals, and significantly more often in stool of workers exposed to sewage water.     

Intervening sequence acquired by lateral gene transfer in Tropheryma whipplei results in 23S rRNA fragmentation

Completion of Tropheryma whipplei genome sequencing may provide insights into the evolution of the molecular mechanisms underlying the pathogenicity of this microorganism. The first postgenomic application was the successful design of a comprehensive culture medium that allows axenic growth of this bacterium, which is particularly recalcitrant to cultivation. This achievement in turn permitted analysis of T. whipplei RNA without contaminating eukaryotic nucleic acids. To obtain high-quality RNA, several extraction methods were compared, but under all conditions tested an atypical profile was observed. By using a Northern blot assay we demonstrated that an insertion sequence previously described in T. whipplei 23S rRNA is in fact an intervening sequence excised during maturation. This cleavage could involve an RNase III identified in the genome of this microorganism. Among the bacteria with a 23S rRNA insertion sequence, T. whipplei is the only gram-positive microorganism. We present phylogenetic evidence that this mobile genetic element was acquired by lateral gene transfer from another enteric bacterium.     

Tropheryma whipplei, the Whipple's disease bacillus, induces macrophage apoptosis through the extrinsic pathway

Tropheryma whipplei, the etiological agent of Whipple''s disease, is an intracellular bacterium that infects macrophages. We previously showed that infection of macrophages results in M2 polarization associated with induction of apoptosis and interleukin (IL)-16 secretion. In patients with Whipple''s disease, circulating levels of apoptotic markers and IL-16 are increased and correlate with the activity of the disease. To gain insight into the understanding of the pathophysiology of this rare disease, we examined the molecular pathways involved in T. whipplei-induced apoptosis of human macrophages. Our data showed that apoptosis induction depended on bacterial viability and inhibition of bacterial protein synthesis reduced the apoptotic program elicited by T. whipplei. Induction of apoptosis was also associated with a massive degradation of both pro- and anti-apoptotic mediators. Caspase-specific inhibition experiments revealed that initiator caspases 8 and 10 were required for apoptosis, in contrast to caspases 2 and 9, in spite of cytochrome-c release from mitochondria. Finally, the effector caspases 3 and 6 were mandatory for apoptosis induction. Collectively, these data suggest that T. whipplei induces apoptosis through the extrinsic pathway and that, beside M2 polarization of macrophages, apoptosis induction contributes to bacterial replication and represents a virulence trait of this intracellular pathogen.     

Intervening Sequence Acquired by Lateral Gene Transfer in Tropheryma whipplei Results in 23S rRNA Fragmentation

Completion of Tropheryma whipplei genome sequencing may provide insights into the evolution of the molecular mechanisms underlying the pathogenicity of this microorganism. The first postgenomic application was the successful design of a comprehensive culture medium that allows axenic growth of this bacterium, which is particularly recalcitrant to cultivation. This achievement in turn permitted analysis of T. whipplei RNA without contaminating eukaryotic nucleic acids. To obtain high-quality RNA, several extraction methods were compared, but under all conditions tested an atypical profile was observed. By using a Northern blot assay we demonstrated that an insertion sequence previously described in T. whipplei 23S rRNA is in fact an intervening sequence excised during maturation. This cleavage could involve an RNase III identified in the genome of this microorganism. Among the bacteria with a 23S rRNA insertion sequence, T. whipplei is the only gram-positive microorganism. We present phylogenetic evidence that this mobile genetic element was acquired by lateral gene transfer from another enteric bacterium.     

Antibodies against recombinant heat shock protein 65 of Tropheryma whipplei in patients with and without Whipple's disease.

Tropheryma whipplei is the causative agent of Whipple's disease (WD), a chronic, life-threatening infection. Laboratory diagnosis is mainly based on PCR and histopathological analysis in duodenal biopsies and other specimens requiring invasive procedures. We have examined the presence of antibodies to recombinant heat shock protein (Hsp65) of T. whipplei in patients with Whipple's disease as well as in control subjects by Western blot and enzyme-linked immunosorbent assay (ELISA). A recombinant plasmid carrying the entire T. whipplei hsp65 gene was constructed, and the expression yielded a 65-kDa histidine-tagged protein. Among four patients with Whipple's disease, two showed an IgG- and one an IgA-response, respectively, when analyzed by Western blotting, whereas from 10 patients without Whipple's disease, only two patients showed a positive IgG-response. The differences between the sera from patients and controls were thus not significant. Successful purification of the protein was achieved by Ni-NTA affinity chromatography. Quantitative analysis of serum antibodies by ELISA demonstrated that antibody levels in the sera of 14 patients were not significantly higher than in those of 89 control subjects. The established ELISA test is not useful to clinical diagnostics.     

抗生素抗性基因连锁传播的侧翼保守元件分析

抗生素在医疗、畜牧和水产养殖业的大量使用造成了环境中耐药细菌和抗性基因的日益增加,也加速了抗性基因在环境细菌间的传播扩散.本研究以环境样本直接提取的总DNA为模板,运用热不对称交错PCR (thermal asymmetric interlaced PCR, Tail-PCR)技术直接扩增抗生素抗性基因上下游序列.通过优化Tail-PCR反应程序,单循环同时扩增出tetW基因的多条侧翼序列,包括6条上游序列和9条下游序列.基于序列的生物信息学分析发现,上游包括一段反向重复序列和已知的一段tetW调节肽序列以及一个已知的插入序列,下游包括一个保守的未知序列和一个开放式阅读框架(the open reading frame,ORF)编码甲基转移酶.结果不仅发现了可能协助tetW基因传播的功能元件,也提供了一个未知侧翼序列高效和便捷的研究方法,即采用Tail-PCR技术,一组样品即能便捷获得多条侧翼序列.     

Analysis of 3'-untranslated regions of seven c-myc genes reveals conserved elements prevalent in post-transcriptionally regulated genes

We have characterized the complete sequence of two c-myc cDNAs from the amphibian Xenopus laevis, and could thus compare the 3'-non-coding sequences of 7 myc cDNAs from 6 species spread over 350 million years of evolution. Although the size of these sequences is heterogeneous, we identified three completely conserved sequences of 10, 11 and 12 contiguous nucleotides. We observed that two of these elements may be contained in conserved stem-loop structures previously implicated in mRNA turnover. The length of these motifs, their existence in conserved predicted structures, and their presence in regulated eukaryote mRNA with a frequency greater than predicted by chance, suggest that they are functionally important.     

The rarity of gene shuffling in conserved genes

Background  

Among three sources of evolutionary innovation in gene function - point mutations, gene duplications, and gene shuffling (recombination between dissimilar genes) - gene shuffling is the most potent one. However, surprisingly little is known about its incidence on a genome-wide scale.     

A conserved family of doublesex-related genes from fishes

The sex-determining gene Mab-3 of C. elegans and the doublesex gene of Drosophila each contain a common DM domain and share a similar role. Human doublesex-related gene DMRT1 also encodes a conserved DM-related DNA-binding domain. We present here the amplification of a broad range of DM domain sequences from three fish species using degenerate PCR. Our results reveal unexpected complexity of the DM domain gene family in vertebrates.     

The mutated subsequence problem and locating conserved genes

MOTIVATION: For the purpose of locating conserved genes in a whole genome scale, this paper proposes a new structural optimization problem called the Mutated Subsequence Problem, which gives consideration to possible mutations between two species (in the form of reversals and transpositions) when comparing the genomes. RESULTS: A practical algorithm called mutated subsequence algorithm (MSS) is devised to solve this optimization problem, and it has been evaluated using different pairs of human and mouse chromosomes, and different pairs of virus genomes of Baculoviridae. MSS is found to be effective and efficient; in particular, MSS can reveal >90% of the conserved genes of human and mouse that have been reported in the literature. When compared with existing softwares MUMmer and MaxMinCluster, MSS uncovers 14 and 7% more genes on average, respectively. Furthermore, this paper shows a hybrid approach to integrate MUMmer or MaxMinCluster with MSS, which has better performance and reliability.