Case report: Brucellosis with rare multiple pulmonary nodules in a depressed patient

BackgroundBrucellosis is a zoonotic disease that threatens public health and creates an economic burden. Unfortunately, it is often overlooked in developing countries, with misdiagnosis causing negative impacts on those with low income. Although the symptoms of brucellosis are commonly reported as fever and fatigue, rare pulmonary, and psychiatric involvements should also be considered. We present the first brucellosis patient in China with multiple pulmonary nodules and depression. Furthermore, this report highlights the importance of collecting patient history in epidemic areas of brucellosis.Case presentationWe report the case of a 40-year-old woman with intermittent fever for 2 months and gradually accompanied by chills, dry cough, arthralgia, and fatigue. The patient was also diagnosed with depression after fever. She received symptomatic treatment at a regional hospital; however, there was no significant symptom relief. She suddenly developed hemoptysis 1 day prior to arrival at our hospital, where we discovered that her liver, spleen, neck, and axillary lymph nodes were enlarged, and there were multiple nodules in both lungs. The patient was eventually diagnosed with brucellosis after the serum agglutination test and received antibiotic therapy, which provided symptom relief.ConclusionThis report describes a case of brucellosis with uncommon multipulmonary nodules and depression in China. This study has widened the evidence of respiratory involvement due to brucellosis. Second, it demonstrates the importance of collecting a comprehensive medical history, especially in epidemic areas. In conclusion, for febrile patients with pulmonary nodules and depression, especially in endemic areas, brucellosis should be considered

Phytotoxic effects of silver nanoparticles and silver ions to Arabidopsis thaliana as revealed by analysis of molecular responses and of metabolic pathways

Conservation Biolog

Evaluation of the taxonomic and functional variation of freshwater plankton communities induced by trace amounts of the antibiotic ciprofloxacin.

Ciprofloxacin (CIP), one of the most frequently detected antibiotics in water systems, has become an aquatic contaminant because of improper disposal and excretion by humans and animals. It is still unknown how trace amounts of CIP affect the aquatic microbial community diversity and function. We therefore investigated the effects of CIP on the structure and function of freshwater microbial communities via 16S/18S rRNA gene sequencing and metatranscriptomic analyses. CIP treatment (7 μg/L) did not significantly alter the physical and chemical condition of the water body as well as the composition of the main species in the community, but slightly increased the relative abundance of cyanobacteria and decreased the relative abundance of eukaryotes. Metatranscriptomic results showed that bacteria enhanced their phosphorus transport and photosynthesis after CIP exposure. The replication, transcription, translation and cell proliferation were all suppressed in eukaryotes, while the bacteria were not affected in any of these aspects. This interesting phenomenon was the exact opposite to both the antibacterial property of CIP and its safety for eukaryotes. We hypothesize that reciprocal and antagonistic interactions in the microcosm both contribute to this result: cyanobacteria may enhance their tolerance to CIP through benefiting from cross-feeding and some secreted substances that withstand bacterial CIP stress would also affect eukaryotic growth. The present study thus indicates that a detailed assessment of the aquatic ecotoxicity of CIP is essential, as the effects of CIP are much more complicated in microbial communities than in monocultures. CIP will continue to be an environmental contaminant due to its wide usage and production and more attention should be given to the negative effects of antibiotics as well as other bioactive pollutants on aquatic environments

Exploring the role of mobile genetic elements in shaping plant–bacterial interactions for sustainable agriculture and ecosystem health

Societal Impact Statement Plants and bacteria interact in complex ways that are crucial to the health and productivity of native vegetation and croplands. While the range of characterised plant‐beneficial bacterial traits continues to grow, key questions remain regarding the distribution and mobility of genes associated with these traits. This work explores the diversity of mobile genetic elements carried by bacteria associated with plant root surfaces, assessing their capacity to help shape plant–bacterial interactions. The significance of this work lies in the potential to contribute to new strategies for enhancing plant health, promoting sustainable agriculture and managing plant diseases in an era when we must respond to environmental change. Summary Integrons are gene capture and expression systems that contribute to bacterial adaptation. Integron research has mainly focused on the role that these elements play in spreading antimicrobial resistance. However, their contribution to niche adaptation is potentially much broader because integrons can sample the vast repertoire of diverse functions encoded by integron gene cassettes. Integrons and gene cassettes have been identified in many bacterial lineages residing in soil and water across varied ecosystems, but there has been little investigation of integrons in plant‐associated bacteria. Bacteria and plants have complex, dynamic relationships that influence plant health and productivity. To investigate whether integrons contribute to adaptative processes in plant microbiomes, we examined gene cassette and microbial taxonomic profiles in rhizoplanes of four important crop species grown under controlled glasshouse conditions. We identified 38,546 unique gene cassettes, including elements carrying genes associated with antibiotic resistance, type II toxin–antitoxin systems and genes with putative functions associated with plant growth promotion, along with a larger set encoding genes of unknown functions. Rhizoplane microbiomes of different plant species showed more similarity in their community composition profiles than in their gene cassette profiles, with complex and distinct suites of gene cassettes associated with each plant species, suggesting that gene cassettes might have a role in specific plant–bacterial interactions. We show that rhizoplane microbiomes carry diverse integron gene cassettes that could play a role in establishing and maintaining rhizoplane communities

The interactive effects of diclofop-methyl and silver nanoparticles on Arabidopsis thaliana: Growth, photosynthesis and antioxidant system.

Diclofop-methyl (DM), a common post-emergence herbicide, is frequently used in agricultural production. Silver nanoparticles (AgNPs) are one of the most widely used nanoparticles, and as such, have been detected and monitored in several environmental systems. Here we investigated the interactive effects of DM and AgNPs on the physiological morphology, photosynthesis and antioxidant system of Arabidopsis thaliana. Our results demonstrated that a 1.0 mg/L DM treatment had no significant effect on the fresh weight of plant shoots and the content of total chlorophyll and anthocyanin. However, a 0.5 mg/L AgNPs treatment was found to significantly inhibit plant growth and chlorophyll synthesis, and was found to cause more severe oxidative damage in plants compared to the effects observed in a hydroponic suspension in which DM and AgNPs were jointly present. Meanwhile, the relative transcript levels of photosynthesis related genes (psbA, rbcL, pgrl1A and pgrl1B) in the combined group were found to be slightly increased compared to transcript levels in the AgNPs group, in order to maintain ATP generation at relatively normal levels in order to repair light damage. One explanation for these observed antagonistic effects was that the existence of DM affects the stability of AgNPs and reduced Ag+ release from AgNPs in the mixed solution. Thereupon, the Ag+-content was found to decrease in shoots and roots in the combined group by 15.2% and 9.4% respectively, compared to the AgNPs group. The coexistence of herbicides and nanomaterials in aquatic environments or soil systems will continue to exist due to their wide usages. Our current study highlights that the antagonistic effects between DM and AgNPs exerted a positive impact on A. thaliana growth

Development of a Potentially New Algaecide for Controlling Harmful Cyanobacteria Blooms Which is Ecologically Safe and Selective.

Harmful cyanobacterial blooms (HCBs) caused by Microcystis aeruginosa are of great concern as they negatively affect the aquatic environment and human health. Chemical methods could rapidly eradicate HCBs and have been used for many decades. However, many chemical reagents are not recommended to eliminate HCBs in the long term, given the possible destructive and toxic effects of the chemicals employed on non-target aquatic organisms. We developed a new algaecide, 2-((1,3,4-thiadiazol-2-yl)thio)-N-(4-chlorophenyl) acetamide (Q2), to control harmful cyanobacteria while being environmentally friendly and selective. In our study, Q2 effectively inhibited cyanobacterial growth, especially of M. aeruginosa, but did not affect eukaryotic algae in test concentrations. A critical mechanism was revealed by transcriptome and metagenomic results showing that Q2 affects multiple cellular targets of cyanobacteria for HCB control, including the destruction of organelles, damage in the photosynthesis center, as well as inhibition of gas vesicle growth, and these changes can be highly relevant to the decrease of quorum-sensing functional KEGG pathways. Furthermore, Q2 did not affect the microbial composition and could recover the disrupted aquatic functional pathways in a short period. This is different from the impact on ecosystem functioning of the traditionally used harmful algaecide diuron. All these results verified that Q2 could be friendly to the aquatic environment, providing a new directional choice in managing HCBs in the future

Development of a Potentially New Algaecide for Controlling Harmful Cyanobacteria Blooms Which is Ecologically Safe and Selective.

Harmful cyanobacterial blooms (HCBs) caused by Microcystis aeruginosa are of great concern as they negatively affect the aquatic environment and human health. Chemical methods could rapidly eradicate HCBs and have been used for many decades. However, many chemical reagents are not recommended to eliminate HCBs in the long term, given the possible destructive and toxic effects of the chemicals employed on non-target aquatic organisms. We developed a new algaecide, 2-((1,3,4-thiadiazol-2-yl)thio)-N-(4-chlorophenyl) acetamide (Q2), to control harmful cyanobacteria while being environmentally friendly and selective. In our study, Q2 effectively inhibited cyanobacterial growth, especially of M. aeruginosa, but did not affect eukaryotic algae in test concentrations. A critical mechanism was revealed by transcriptome and metagenomic results showing that Q2 affects multiple cellular targets of cyanobacteria for HCB control, including the destruction of organelles, damage in the photosynthesis center, as well as inhibition of gas vesicle growth, and these changes can be highly relevant to the decrease of quorum-sensing functional KEGG pathways. Furthermore, Q2 did not affect the microbial composition and could recover the disrupted aquatic functional pathways in a short period. This is different from the impact on ecosystem functioning of the traditionally used harmful algaecide diuron. All these results verified that Q2 could be friendly to the aquatic environment, providing a new directional choice in managing HCBs in the future

Offspring toxicity of silver nanoparticles to Arabidopsis thaliana flowering and floral development.

Environmental Biolog

Factors promoting thrombosis in essential thrombocythemia: a Meta-analysis

ObjectiveTo further understand the factors that promote thrombosis in essential thrombocythemia （ET） that were not included in IPSET-thrombosis （International Prognostic Score of Thrombosis for ET）. MethodsA systematic evaluation was conducted on 292 studies by retrieving PubMed，Web of Science, and The Cochrane Library. The incidence and relative risk ratio （RR） of thrombosis in ET patients with different risk factors were calculated. The confidence levels for the outcome were analyzed in combination with RR values and recommendation scores (RS) to find the thrombotic risk factors in ET patients. ResultsOut of 9 risk factors that promoted ET thrombosis, there were 4 factors in IPSET-thrombosis, including history of thrombosis （35.0%, RR=3.30, 95% CI : 2.30-4.75）, JAK2V617F positive （21.0%, RR=2.28, 95%CI : 1.14-4.56）, age over 60 years old （ 22.4% , RR=1.95, 95%CI : 1.17-3.23） and cardiovascular risk factors （17.7%, RR =1.90, 95%CI : 1.08-3.35）. The remaining five risk factors, not listed in IPSET-thrombosis, included monoclonal type of ET based on X-chromosome inactivation pattern （XCIP, 30.6%, RR=4.49, 95% CI: 1.58-12.77）, high JAK2V617F burden （33.9%, RR=3.69, 95%CI: 1.70-7.99）, leukocytosis （18.7%, RR=3.05, 95%CI: 1.81-5.13）, MPL mutation （22.1%, RR=2.40, 95%CI: 1.08-5.33） and splenomegaly （25.6%, RR=1.76, 95%CI：1.29-2.40）. ConclusionAmong the risk factors promoting thrombosis in ET patients, five thrombotic risk factors not included in the IPSET-thrombosis have been identified

Phyllosphere Microorganisms: Sources, Drivers, and Their Interactions with Plant Hosts.

The leaves of plants are colonized by various microorganisms. In comparison to the rhizosphere, less is known about the characteristics and ecological functions of phyllosphere microorganisms. Phyllosphere microorganisms mainly originate from soil, air, and seeds. The composition of phyllosphere microorganisms is mainly affected by ecological and abiotic factors. Phyllosphere microorganisms execute multiple ecological functions by influencing leaf functions and longevity, seed mass, fruit development, and homeostasis of host growth. A plant can respond to phyllosphere microorganisms by secondary metabolite secretion and its immune system. Meanwhile, phyllosphere microorganisms play an important role in ecological stability and environmental safety assessment. However, as a result of the instability of the phyllosphere environment and the poor cultivability of phyllosphere microorganisms in the current research, there are still many limitations, such as the lack of insight into the mechanisms of plant–microorganism interactions, the roles of phyllosphere microorganisms in plant growth processes, the responses of phyllosphere microorganisms to plant metabolites, etc. This review summarizes the latest progress made in the research of the phyllosphere in recent years. This is beneficial for deepening our understanding of phyllosphere microorganisms and promoting the research of plant–atmosphere interactions, plant pathogens, and plant biological control.Environmental Biolog