Search Results (278)

Background: Wild-type transthyretin cardiac amyloidosis (ATTRwt-CM) is a frequent but underdiagnosed cause of heart failure with preserved ejection fraction (HFpEF) and left ventricular hypertrophy (LVH). Early identification is essential given the availability of disease-modifying therapies. The T-Amylo and Davies scores are non-invasive tools for estimating ATTR CM probability, but their comparative performance in the same real-world population is not well defined. Objectives: To compare the diagnostic accuracy of T-Amylo and Davies scores in consecutive patients referred for suspected cardiac amyloidosis. Methods: We retrospectively analyzed 81 patients (mean age 76.8 ± 8.3 years, 74% male) who underwent a standardized work-up: ECG, echocardiography with strain, NT-proBNP and troponin, bone scintigraphy, and immunofixation. ATTR CM was diagnosed according to established non-biopsy criteria. Both scores were calculated retrospectively, and sensitivity, specificity, predictive values, accuracy, and agreement were assessed. Results: ATTR CM was confirmed in 28 patients (34.5%). T-Amylo showed higher sensitivity (91.2% vs. 73.5%) and NPV (89.7% vs. 79.1%), while Davies had greater specificity (85.0% vs. 65.0%) and PPV (80.5% vs. 70.8%). Overall accuracy was comparable (T-Amylo 77.0% vs. Davies 79.7%). Agreement between scores was moderate (κ = 0.59). Conclusions: T-Amylo is best suited as a screening tool for suspected ATTR CM, while Davies offers confirmatory value in high-probability cases. Combining these tools in a sequential strategy may optimize diagnostic efficiency, reduce unnecessary testing, and expedite initiation of disease-modifying therapy. Full article

Improving the efficacy of microbial biocontrol agents is a pivotal strategy for sustainable management of rice blast and sheath blight caused by Pyricularia oryzae and Rhizoctonia solani, respectively, in Vietnam. In this study, Trichoderma sp. TVN-A0 and Trichoderma sp. TVN-H0 were irradiated by gamma to generate mutants for screening the enhanced antagonistic activity against P. oryzae and R. solani. The potential mutants were screened by antifungal metabolite production via the cellophane membrane assay (I_CM), antagonistic performance through dual culture confrontation assays (I_DC), volatile organic compound bioassays (I_VOCs), and chitinase activity. As a result, among five potential mutants derived from each wild-type strain (AM1-AM5 and HM1-HM5), mutant AM2 originated from TVN-A0, and mutant HM2 derived from TVN-H0 demonstrated the highest inhibition rates and chitinase activities. The AM2 exhibited I_CM of 96.71% against R. solani, 92.57% against P. oryzae, I_DC of 87.76%, and I_VOCs of 83.57%, while HM2 possessed I_CM of 95.33% against R. solani, 85.28% against P. oryzae, I_DC of 91.24%, and I_VOCs of 79.33%. The genetic differences among mutants and their parents were investigated by RAPD. The non-GMO AM2 and HM2 mutants are promising candidates for biocontrol of the diseases caused by P. oryzae and R. solani in Vietnam. Full article

The molecular basis for the distinct intestinal tropism of infectious bronchitis virus (IBV) strains remains poorly understood. This study identifies the S2 subunit of the spike glycoprotein as the critical determinant conferring duodenal tropism to the IBV CSL strain. Comparative pathogenesis in specific-pathogen-free (SPF) chicks revealed that the CSL strain achieved significantly higher viral titers in the duodenum compared to strains D90, PYG QX1, and XXX QX5. This duodenal replication was associated with severe epithelial inflammation, characterized by upregulation of pro-inflammatory cytokines (IL-6, IL-17A, IL-22, TNF-α, IFN-β, IFN-γ) and disruption of barrier integrity via downregulation of tight junction proteins (Occludin, Claudin-1, ZO-1). Crucially, reverse genetics using the non-enterotropic D90 backbone demonstrated that recombinant viruses carrying the CSL-S2 gene (rD90-ΔS/CSL and rD90-ΔS2/CSL), but not those carrying CSL-S1 (rD90-ΔS1/CSL), replicated efficiently and induced inflammation in the duodenum, phenocopying wild-type CSL. In contrast, renal tropism was independent of the S2 subunit. These findings establish the S2 subunit as both necessary and sufficient for IBV duodenal tropism, uncoupling it from renal pathogenicity. This identifies S2 as a prime molecular target for developing next-generation vaccines against intestinal IBV pathotypes. Full article

Purpose: The adenoid microbiota plays a key role in adenoid hypertrophy (AH). This study explored the molecular epidemiology and antimicrobial resistance of Haemophilus. Influenzae (H. influenzae) strains in pediatric AH patients. Methods: Retrospective analysis of pediatric AH patients undergoing endoscopic adenoidectomy. Adenoid tissue samples were cultured to screen for pathogens. H. influenzae strains were identified by 16S rRNA sequencing and serotyped via q-PCR. Multilocus sequence typing (MLST) and ftsI gene analysis were conducted using PubMLST. β-lactamase genes (bla_TEM-1, bla_ROB-1) were detected by PCR, and antibiotic susceptibility testing (AST) was performed using the Etest method. For imipenem-resistant strains, the acrRAB efflux pump gene cluster and ompP2 porin gene were sequenced and compared with those of the wild-type strain Rd KW20. Results: Over 8 months, 56 non-duplicate H. influenzae strains were isolated from 386 patients. The detection rate was highest in children under 5 years (30.5%) compared to those aged 5–10 years (13.4%) and 10–15 years (8.7%). Of 49 sub-cultured strains, all were non-typeable H. influenzae (NTHi). MLST identified 22 sequence types (STs) and 13 clonal complexes (CCs), with CC11 (26.5%), CC3 (14.3%), and CC107 (14.3%) being predominant. Common STs included ST103 (22.4%), ST57 (10.2%), and ST107 (10.2%). Most strains belonged to the ftsI group III-like+ (57.1%). β-lactamase positivity was 98.0% (48/49), with bla_TEM-1 (95.9%) and bla_ROB-1 (18.4%) detected. AST showed low susceptibility to ampicillin (10.2%), amoxicillin–clavulanate (34.7%), azithromycin (12.2%), and trimethoprim–sulfamethoxazole (14.3%). Among the β-lactamase-positive strains, 44/48 were β-lactamase-positive ampicillin-resistant (BLPAR); none were β-lactamase-negative ampicillin-resistant (BLNAR). Imipenem susceptibility was 91.8% (45/49). No carbapenemases were found in the imipenem-resistant strains, but mutations in acrRAB (88.12–94.94% identity) and ompP2 (77.10–82.94% identity) were observed. Conclusions: BLPAR NTHi strains of CC11 are major epidemic strains in pediatric AH. Imipenem resistance in H. influenzae likely results from porin mutations rather than carbapenemase activity. Enhanced surveillance of H. influenzae’s role in AH and its resistance patterns is warranted. Full article

Oral microbiota have been implicated in pancreatic ductal adenocarcinoma (PDAC) and may contribute to chemotherapy resistance. While previous studies attributed bacteria-induced resistance to indirect host modulation, recent findings suggest a direct mechanism. Escherichia coli expressing long-form cytidine deaminase (CDD_L) can degrade gemcitabine, a chemotherapeutic agent, into a non-toxic form, leading to resistance. In contrast, bacteria carrying short form (CDD_S) or lacking CDD did not induce resistance. This study investigates whether oral bacteria can cause gemcitabine resistance in PDAC cells through CDD-mediated degradation. Oral microbes associated with PDAC were selected based on CDD isoforms: Aggregatibacter actinomycetemcomitans carrying CDD_L, Enterococcus faecalis, Streptococcus mutans, Porphyromonas gingivalis, all carrying CDD_S, and Fusobacterium nucleatum lacking CDD. The selected microbes, along with wild-type and CDD-deficient E. coli, were co-incubated with gemcitabine to assess its degradation and PDAC cell proliferation. A. actinomycetemcomitans fully degraded gemcitabine and induced resistance. Surprisingly, CDD_S-expressing oral bacteria partially degraded gemcitabine in a strain-dependent manner. Expressing either CDD_L or CDD_S in CDD-deficient E. coli resulted in equivalent gemcitabine degradation and resistance, indicating that CDD function is independent of isoform length. These findings highlight the role of oral bacteria in gemcitabine resistance and the need for strategies to mitigate microbial-driven resistance in PDAC treatment. Full article

Prion diseases are classically attributed to the accumulation of protease-resistant prion protein (PrP^Sc); however, recent evidence suggests that alternative misfolded prion conformers and systemic inflammatory factors may also contribute to neurodegeneration. This study investigated whether recombinant moPrP^Res, generated by incubating wild-type mouse PrP^C with bacterial lipopolysaccharide (LPS), can induce prion-like disease in FVB/N female mice, whether LPS alone causes neurodegeneration, and how LPS modulates disease progression in mice inoculated with the Rocky Mountain Laboratory (RML) strain of prions. Wild-type female FVB/N mice were randomized into six subcutaneous treatment groups: saline, LPS, moPrP^Res, moPrP^Res + LPS, RML, and RML + LPS. Animals were monitored longitudinally for survival, body weight, and clinical signs. Brain tissues were analyzed histologically and immunohistochemically for vacuolar degeneration, PrP^Sc accumulation, reactive astrogliosis, and amyloid-β plaque deposition. Recombinant moPrP^Res induced a progressive spongiform encephalopathy characterized by widespread vacuolation and astrogliosis, yet with no detectable PrP^Sc by Western blot or immunohistochemistry. LPS alone triggered a distinct neurodegenerative phenotype, including cerebellar amyloid-β plaque accumulation and terminal-stage spongiosis, with approximately 40% mortality by the end of the study. Co-administration of moPrP^Res and LPS resulted in variable regional pathology and intermediate survival (50% at 750 days post-inoculation). Interestingly, RML + LPS co-treatment led to earlier clinical onset and mortality compared to RML alone; however, vacuolation levels were not significantly elevated and, in some brain regions, were reduced. These results demonstrate that chronic endotoxemia and non-infectious misfolded PrP conformers can independently or synergistically induce key neuropathological hallmarks of prion disease, even in the absence of classical PrP^Sc. Targeting inflammatory signaling and toxic prion intermediates may offer novel therapeutic strategies for prion and prion-like disorders. Full article

Secreted bacteriolytic proteases L1 and L5 of the Gram-negative bacterium Lysobacter capsici XL hydrolyze peptide bridges in bacterial peptidoglycans. Such specificity of action determines the prospects of these enzymes for medicine with the view of creating new antimicrobial drugs to combat antibiotic-resistant strains of pathogens. This research concerns the development of successful expression systems for producing active enzymes L1 and L5 in sufficient amounts for comprehensive studies. Based on L. capsici XL strains with deletions in the alpA (enzyme L1) and alpB (enzyme L5) genes and the constructed expression vectors pBBR1-MCS5 P_T5–alpA and pBBR1-MCS5 P_T5–alpB, we obtained expression strains L. capsici P_T5–alpA and L. capsici P_T5–alpB, respectively. The yields of enzymes L1 and L5 in the developed strains increased by 4 and 137 times, respectively, as compared to the wild-type strain. The cultivation of the expression strains was successfully scaled up under non-selective conditions in a 10-L bioreactor. After fermentation, the yields of enzymes L1 and L5 were 35.48 mg/L and 57.11 mg/L, respectively. The developed homologous expression systems of bacteriolytic proteases L1 and L5 have biotechnological value as compared to those obtained by us earlier based on heterologous expression systems, which have lower yields and labor-intensive purification schemes. Full article

The germline stem cells (GSCs) in the male gonad of Drosophila can increase their division frequency in response to a demand for more sperm caused by repeated mating. However, the molecules and mechanisms regulating and mediating this response have yet to be fully explored. Here, we present the results of a transcriptome analysis comparing expression from the testis tips from non-mated and mated males. An overlapping set of 18 differentially expressed genes (DEGs) from two independent wild-type (wt) strains revealed that the majority of the DEGs encode secreted proteins, which suggests roles for them in cell–cell interactions. Consistent with a role for secretion in regulating GSC divisions, knocking down Signal Recognition Particle (SRP) components within the germline cells using RNA Interference (RNAi), prevented the increase in GSC division frequency in response to mating. The major class of DEGs encodes polypeptides below the size of 250 amino acids, also known as small proteins. Upon reducing germline expression of small proteins, males no longer increased GSC division frequency after repeated mating. We hypothesize that mating induces cellular interactions via small proteins to ensure continued GSC divisions for the production of sperm. Full article

Background/Objective: Platelet concentrates (PCs) are used in transfusion medicine to treat bleeding disorders. Staphylococcus aureus, a predominant PC contaminant, has been implicated in several adverse transfusion reactions. The aim of this study was to investigate the impact of PC storage on S. aureus resistance to quinolones, which are commonly used to treat S. aureus infections. Methods/Results: Four transfusion-relevant S. aureus strains (TRSs) were subjected to comparative transcriptome analyses when grown in PCs vs. trypticase soy broth (TSB). Results of these analyses revealed differentially expressed genes involved in antibiotic resistance. Of interest, the norB gene (encodes for the NorB efflux pump, which is implicated in quinolone resistance and is negatively regulated by MgrA) was upregulated (1.2–4.7-fold increase) in all PC-grown TRS compared to TSB cultures. Minimal Bactericidal Concentration (MBC) of ciprofloxacin and norfloxacin in PC-grown TRS compared to TSB showed increased resistance to both quinolones in PC cultures. Complementary studies with non-transfusion-relevant strains S. aureus RN6390 and its norB and mgrA deletion mutants were conducted. MBC of ciprofloxacin and norfloxacin and RT-qPCR assays of these strains showed that not only norB, but also norA and norC may be involved in enhanced quinolone resistance in PC-grown S. aureus. The role of norB in S. aureus virulence was also tested using the silkworm Bombyx mori animal model; lethal dose 50 (LD₅₀) assays revealed slightly higher virulence in larvae infected with the wild-type strain compared to the norB mutant. Conclusions: The PC storage environment enhances quinolone resistance in S. aureus and induces differential expression of efflux pump nor genes. Furthermore, our preliminary data of the involvement of NorB in virulence of S. aureus using a silkworm model merit further investigation with other systems such as a mammal animal model. Our results provide mechanistic insights to aid clinicians in the selection of antimicrobial treatment of patients receiving transfusions of S. aureus-contaminated PCs. Full article

Fed-batch cultivation is a widely used strategy for microbial lipid production, offering flexibility in nutrient control and the potential for high lipid productivity. However, optimizing feeding strategies remains a complex challenge, as it depends on multiple factors, including strain-specific metabolism and process limitations. In this study, we developed a computational framework based on dynamic flux balance analysis and small-scale metabolic models to evaluate and optimize lipid production in Rhodosporidium toruloides strains. We proposed equations to estimate both the carbon and energy source mass feed rate ($F_{in}·s_r$) and its concentration in the feed ($s_r$) based on lipid accumulation targets, and defined minimum feeding flow rate ($F_{in}$) according to process duration. We then assessed the impact of these parameters on commonly used bioprocess metrics—lipid yield, titer, productivity, and intracellular accumulation—across wild-type and engineered strains. Our results showed that the selection of $F_{in}·s_r$ was strongly strain-dependent and significantly influenced strain performance. Moreover, for a given $F_{in}·s_r$, the specific values of $s_r$, and the resulting $F_{in}$, had distinct and non-equivalent effects on performance metrics. This methodology enables the rational pre-selection of feeding strategies and strains, improving resource efficiency and reducing the probability of failed experiments. Full article

The composition of the gut microbiome, defined by environmental factors, significantly affects research outcomes, with variations observed across animal facilities. Efforts to standardize led to the definition of the ‘Altered Schaedler flora’ (ASF), comprising eight bacterial groups. Our data highlights the variability of ASF under pathogen contact. Feces from two wild-type strains (C57Bl/6J and Balb/c mice) with and without proven infection was collected in two different animal facilities and analyzed. The data show a significant difference in the quantity (either reduction or increase) of the eight ASF bacterial groups when comparing infected and non-infected mice across different housing areas (SPF-specific pathogen-free, quarantine, and conventional-experimental areas) within a facility, as well as in comparison to another facility. Furthermore, strain-specific differences are also evident, with certain ASF groups showing a reduction in quantity at one facility but an increase at the other, comparing the same housing area. Comparative studies across facilities confirmed the necessity of baseline determination for accurate ASF analysis. Performing ASF analysis, facilitated by in-house qPCR (quantitative polymerase chain reaction) kits, offers prompt and precise microbiome profiling, enhancing experimental accuracy and health monitoring in animal research settings. Full article

HIV/AIDS and Mycobacterial tuberculosis (Mtb) are the leading cause of deaths worldwide. Thus, better medicaments are required to manage these diseases. Quinolines have shown great potential due to their broad spectrum of biological activity. Thus, quinoline–1,2,3-triazole–aniline hybrids were synthesised in moderate to good yields. Compounds 11g (IC₅₀ = 0.388 µM), 11h (IC₅₀ = 0.01032 µM) and 11i (IC₅₀ = 0.167 µM) exhibited the most promising in vitro activities against the wild-type HIV-1 subtype B, with 11h being 9-fold more active than AZT (IC₅₀ = 0.0909 µM), the reference drug. Furthermore, compound 11h displayed moderate activity, with a MIC₉₀ of 88μM against Mtb’s H37Rv strain. Cytotoxicity studies on TZM-bl cell lines revealed that most of the tested compounds were generally non-cytotoxic; the selectivity index (SI) for 11h, the front runner, is >2472. Molecular docking studies revealed that 11h interacted with Phe112, Tyr108, Glu283 and Trp86 amino acid residues in the active site of HIV-1. DFT studies revealed that 11h has the ability to donate and accept electrons to and from available orbitals. The predicted ADMET studies showed that these compounds possess drug-likeness, and 11h has the potential for further optimisation as an anti-HIV-1 agent. Full article

SARS-CoV-2 is classified as a containment level 3 (CL3) pathogen, limiting research access and antiviral testing. To address this, we developed a non-infectious viral surrogate system using reverse genetics to generate sub-genomic replicons. These replicons contained the nsp1 mutations K164A and H165A and had the spike, membrane, ORF6, and ORF7a coding sequences replaced with various reporter and selectable marker genes. Replicons based on the ancestral Wuhan Hu-1 strain and the Delta variant of concern were replication-competent in multiple cell lines, as assessed by Renilla luciferase activity, fluorescence, immunofluorescence staining, and single-molecule fluorescent in situ hybridization. Antiviral assays using transient replicon expression showed that remdesivir effectively inhibited both replicon and viral replication. Ritonavir and cobicistat inhibited Delta variant replicons similarly to wild-type virus but did not inhibit Wuhan Hu-1 replicon replication. To further investigate the impact of nsp1 mutations, we generated a recombinant SARS-CoV-2 virus carrying the K164A and H165A mutations. The virus exhibited attenuated replication across a range of mammalian cell lines, was restricted by the type I interferon response, and showed reduced cytopathic effects. These findings highlight the utility of sub-genomic replicons as reliable CL2-compatible surrogates for studying SARS-CoV-2 replication and drug activity mechanisms. Full article

Selenium-binding protein 1 (SeBP1) is an anticancer factor that affects lipid metabolism in mouse kidneys via the peroxisome proliferator-activated receptor-alpha (PPARA) pathway. However, its physiological role in the liver is difficult to explain because of the presence of the highly homologous selenium-binding protein 2 (SeBP2). To investigate the role of these proteins in the liver, we generated SeBP1 and SeBP2 double-knockout mice (SeBP1/2-DK). SeBP1/2 deletion did not significantly alter the mice phenotypic compared to that of the wild-type strain. Then, we identified the genes involved in hepatic lipid metabolism. The double knockout did not affect fatty acid and cholesterol synthesis, but inhibited fatty acid oxidation and cholesterol efflux. Furthermore, transfection of HepG2 cells with human selenium-binding protein 1 (hSeBP1) positively regulated PPARA and the genes controlled by it. Overexpression of hSeBP1 reduced the levels of non-esterified fatty acids in the culture medium. The serum levels of low-density lipoprotein cholesterol, high-density lipoprotein cholesterol, and triglycerides were significantly different among the three groups. In summary, we elucidated the potential signaling pathways of SeBP1 and SeBP2 in fatty acid oxidation and hepatic cholesterol efflux. Our findings provide insights relevant for developing new strategies to prevent and treat lipid metabolism disorders. Full article

Laccases are synthesized by a diverse range of fungi. Nevertheless, despite the industrial significance of laccases, the regulatory mechanism governing laccase production has been relatively understudied. This research aims to explore the regulatory function of the methyltransferase CcLaeA in laccase biosynthesis using the newly isolated fungal strain Curvularia clavata J1. Through CRISPR-Cas9-mediated gene disruption, the deletion of CclaeA led to a 1.5-fold increase in extracellular laccase activity in the ΔCclaeA mutant when compared to the wild-type strain. This finding indicates that CcLaeA functions as a transcriptional repressor of laccase biosynthesis. Transcriptomic analysis demonstrated that CcLaeA does not directly regulate the expression of laccase genes. Instead, it modulates genes associated with hydrolases and peptidases. This modulation potentially reduces the enzymatic degradation of laccase at the protein level. This study significantly enhances our understanding of fungal laccase regulation. By establishing a connection between the deletion of CclaeA and the improvement of enzyme stability and activity, this research offers practical insights for engineering fungal strains to optimize laccase yields for bioremediation and biofuel applications. Furthermore, the integration of targeted gene knockout with multi-omics validation sets up a methodological framework for investigating regulatory networks in non-model fungi. This framework is expected to accelerate the development of sustainable biocatalysts, thereby contributing to the advancement of biotechnology in various industrial sectors. Full article