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Pakistan has a huge sheep population (37.2 million in 2024) that is largely unexplored for the presence of vector transmitted parasites. Present study was aimed to document the prevalence of Anaplasma sp. , Anaplasma ovis , Theileria ovis and Theileria lestoquardi in sheep blood samples (N = 329) that were collected from six districts (Muzaffargarh, Rajanpur, Dera Ghazi Khan, Layyah, Taunsa and Khanewal) during August till December 2024 and to report the genetic diversity of screened pathogens. Molecular analyses revealed that the prevalence of Anaplasma sp. , Anaplasma ovis and Theileria ovis in screened sheep was 11%, 20% and 21% respectively. None of the screened sheep was Theileria lestoquardi infected. Co-infection of the screened pathogens was also observed. Presence of the detected pathogens was confirmed by DNA sequencing and subsequent BLAST analysis. Phylogenetic analysis revealed that these pathogens displayed genetic similarities with the sequences that were deposited from various countries across the globe. Prevalence of all screened pathogens varied significantly between the sampling districts. Similarly, the Anaplasma sp., Anaplasma ovis and Theileria ovis prevalence varied significantly among the sheep breeds. Anaplasma ovis infection was more common in large herds and in un-infested sheep. Theileria ovis infection was more frequent in small herds. In conclusion, we are reporting the presence of Anaplasma sp., Anaplasma ovis and Theileria ovis in Pakistani sheep that were enrolled from all six districts. Large-scale studies are recommended in various geo-climatic regions of Pakistan to confirm the genetic diversity, epidemiology and host-pathogen interactions that will contribute towards effective control of these infections among the local sheep population.

Ischemic stroke is categorized by either permanent or transient blood flow obstruction, impeding the distribution of oxygen and essential nutrients to the brain. In this study, we examined the neuroprotective effects of compound A3, a synthetic polyphenolic drug product, against ischemic brain injury by employing an animal model of permanent middle cerebral artery occlusion (p-MCAO). Ischemic stroke induced significant elevation in the levels of reactive oxygen species and, ultimately, provoked inflammatory cascade. Here, we demonstrated that A3 upregulated the endogenous antioxidant enzymes, such as glutathione s-transferase (GST), glutathione (GSH), and reversed the ischemic-stroke-induced nitric oxide (NO) and lipid peroxidation (LPO) elevation in the peri-infarct cortical and striatal tissue, through the activation of endogenous antioxidant nuclear factor E2-related factor or nuclear factor erythroid 2 (Nrf2). In addition, A3 attenuated neuroinflammatory markers such as ionized calcium-binding adapter molecule-1 (Iba-1), cyclooxygenase-2 (COX-2), tumor necrotic factor-α (TNF-α), toll-like receptors (TLR4), and nuclear factor-κB (NF-κB) by down-regulating p-JNK as evidenced by immunohistochemical results. Moreover, treatment with A3 reduced the infarction area and neurobehavioral deficits. We employed ATRA to antagonize Nrf2, which abrogated the neuroprotective effects of A3 to further assess the possible involvement of the Nrf2 pathway, as demonstrated by increased infarction and hyperexpression of inflammatory markers. Together, our findings suggested that A3 could activate Nrf2, which in turn regulates the downstream antioxidants, eventually mitigating MCAO-induced neuroinflammation and neurodegeneration.

Nanoparticles synthesized from green sources have attracted great recognition in the present times, which can be ascribed to their distinctive attributes and diversified applicability. Therefore, the present study employed Ocimum basilicum seed extract to synthesize silver nanoparticles. UV–vis spectrophotometry revealed strenuous peaks for different concentrations of silver nanoparticles ranging between 400 and 430 nm. The average crystal size calculated using X-ray diffraction analysis was 6.7 nm. Energy-dispersive X-ray analysis clearly displayed the presence of silver ions in the elemental structure of the synthesized nanoparticles. The morphology of synthesized nanoparticles revealed by scanning electron microscopy was documented in terms of spherical shape surrounded by an organic layer and nanoparticle size was estimated to be in between 10 and 80 nm. The nanoparticles exhibited substantial antibacterial activity against 46 foodborne bacterial isolates and 15 clinical isolates of Klebsiella pneumoniae, with the largest inhibition zones measuring 24 and 13 mm, respectively. Minimum inhibitory concentration values ranged between 500 and 800 µl/ml for various isolates. The antibacterial effect of all antibiotics revealed considerable enhancement when combined with nanoparticles. The calculated fractional inhibitory concentration index values were < 1 validating excellent synergism between nanoparticles and all antibiotics except ciprofloxacin against the majority of bacterial isolates. Interestingly, the biogenic nanoparticles showed significant antioxidant potential with IC50 value of 165 µg/ml as well as anti-inflammatory activity with an IC50 value of 82 µg/ml. Conclusively, the seed extract of Ocimum basilicum can be prospected for the development of antibacterial silver nanoparticles against pathogenic bacteria.

As part of the growing evolution in nanotechnology and thermal sciences, nanoparticles are considered as an alternative solution for the energy depletion due to their ultra-high thermal effectives. Nanofluids reflect inclusive and broad-spectrum significances in engineering, industrial and bio-engineering like power plants, energy source, air conditioning systems, surface coatings, evaporators, power consumptions, nano-medicine, cancer treatment, etc. The present study describes the bio-convective peristaltic flow of a third-grade nanofluid in a tapered asymmetric channel. Basic conservation laws of mass, momentum, energy, and concentration as well as the microorganism diffusion equation are utilized to model the problem. The simplified form of the modeled expressions is accounted with long wavelength assumptions. For solving the resulting coupled and nonlinear equations, a well-known numerical method implicit finite difference scheme has been utilized. The graphical results describe the velocity, temperature and concentration profiles, and the density of motile microorganisms at the nanoscale. Furthermore, microorganism concentration lines are analyzed.

The poultry industry plays a major role in the emergence and spread of foodborne zoonotic diseases, particularly those associated with antibiotic-resistant bacteria. These diseases pose substantial global public health challenges, and the increasing development of antimicrobial resistance further intensifies these concerns. In response, scientific efforts have expanded to develop and implement innovative technologies capable of mitigating the rising prevalence of multidrug-resistant (MDR) microorganisms. Therapeutic bacteriophage supplementation has regained significant attention because it can selectively lyse specific bacteria, is cost-effective to produce, offers environmentally favorable characteristics, and provides several advantages over conventional antibiotics. Experimental studies have demonstrated that phage therapy is both safe and effective for controlling poultry-associated enteric pathogens. Phages can be applied at various stages of the poultry production chain, from rearing to processing and distribution, using multiple delivery strategies. Despite certain limitations, the targeted and well-regulated application of phage cocktails offers considerable potential as an alternative to antibiotics for managing MDR infections. The success of bacteriophage therapy depends on several factors, including the timing of administration, dosage, delivery method, and its integration with other therapeutic approaches. Therefore, developing a comprehensive understanding of bacteriophage utilization in poultry production is both timely and necessary. This review examines the applications, constraints, and future opportunities of phage therapy within the commercial poultry industry, with particular emphasis on the mechanisms through which bacteriophages control bacterial infections.

Plant immunity includes enemy recognition, signal transduction, and defensive response against pathogens. We experimented to identify the genes that contribute resistance against dieback disease to Dalbergia sissoo , an economically important timber tree. In this study, we investigated the role of three differentially expressed genes identified in the dieback-induced transcriptome in Dalbergia sissoo. The transcriptome was probed using DOP-rtPCR analysis. The identified RGAs were characterized in silico as the contributors of disease resistance that switch on under dieback stress. Their predicted fingerprints revealed involvement in stress response. Ds-DbRCaG-02-Rga.a, Ds-DbRCaG-04-Rga.b, and Ds-DbRCaG-06-Rga.c showed structural homology with the Transthyretin-52 domain, EAL associated YkuI_C domain, and Src homology-3 domain respectively, which are the attributes of signaling proteins possessing a role in regulating immune responses in plants. Based on in-silico structural and functional characterization, they were predicted to have a role in immune response regulation in D. sissoo.

Cyanobacteria, a group of oxygenic photosynthetic prokaryotes, are emerging as promising biofactories for the eco-benign and sustainable production of metal oxide nanoparticles. These blue-green algae are particularly grabbing attention for nanoparticle biosynthesis owing to their potential to produce unique metabolites that can successfully reduce and cap nanoparticles. The current research explores the use of an organic biomass extract of indigenous Nostoc sp. SI-SN for the biofabrication of zinc oxide nanoparticles (ZnO-NPs). Their successful synthesis was confirmed with UV–Vis, FTIR, XRD, and SEM analyses with a 370-nm absorption band and a crystal size of 18.47 nm, showing a quasi-spherical to hexagonal morphology due to capping and stabilization by polyphenolic compounds. The ZnO-NPs showed antibacterial potential against clinical pathogens, with minimum inhibitory concentrations (MICs) ranging from 10.06 to 48.5 µg/ml. They also demonstrated anti-exopolysaccharide, anti-biofilm, and anti-quorum sensing activity up to 86, 100, and 88%, respectively, at a sub-MIC value of 32 µg/ml after 24 h. They also possessed potent antioxidant potential, with an EC 50 value of 39.51 µg/ml. No significant genotoxic effect was recorded against plasmid DNA at or below the concentration of 25 µg/ml after 4 h. Furthermore, seed germination, seedling parameters, and chlorophyll content were significantly enhanced with ZnO-NPs at concentrations of 10 and 15 µg/ml in corn and wheat, respectively. Thus, the organic biomass extract of  Nostoc sp. SI-SN could be used as a safe, sustainable, and green alternative for the production of multifunctional ZnO-NPs, not only in the biomedical field but also as nano-fertilizers in agricultural applications for sustainable development. Graphic Abstract