The rockefeller university

Oxytocin, an evolutionarily conserved neuropeptide, plays a crucial role in various physiological and behavioural processes, offering potential therapeutic benefits for several psychiatric and neurodevelopmental conditions. Despite its promise, oxytocin research has been marked by inconsistent results concerning its therapeutic applications and underlying mechanisms. Performing a systematic review and meta-analysis is a popular approach to shed light on mixed findings in a body of literature; however, they can become quickly outdated as new evidence becomes available. Given these challenges, research on the links between oxytocin and biobehavioural outcomes is ideally positioned for the adoption of 'living' meta-analyses, which allow for the continuous integration of new data and updated conclusions. Here we introduce the Active Monitoring of Oxytocin Research Evidence (AMORE) platform (https://amore-project.org), which is a hub that aggregates articles and materials associated with living meta-analyses for biobehavioural oxytocin research in humans. Developed through consensus among 24 expert researchers, a standardized framework was established that either requires or recommends practices ensuring transparency and rigor in living meta-analyses featured on the AMORE platform. Overall, AMORE has been designed to advance human oxytocin biobehavioural research by the timely integration of emerging evidence through transparent living meta-analyses. To date, two living meta-analysis projects at different stages of publication are hosted on AMORE, demonstrating the platform's practical application.

The complement system is a central component of innate and shaping adaptive responses. Deficiencies in complement proteins, whether inherited or acquired, predispose to severe infections, particularly with encapsulated bacteria such as Neisseria meningitidis and Streptococcus pneumoniae. Although rare, inherited defects affect different pathways and may also present with autoimmune or renal diseases. Diagnosis relies on functional and quantitative assays, especially in patients with earlyonset or recurrent infections. Complement inhibition, introduced with eculizumab and expanded to agents targeting C3, Factor B, or Factor D, has transformed the management of complement-mediated disorders but unmasked novel infectious risks, including meningococcal disease and invasive fungal infections.

Immunodeficient mice, particularly the NOD.Cg-Prkdc scid Il2rg tm1Wjl /SzJ (NSG) strain and other non-obese diabetic (NOD)-derived lines are widely used in biomedical research due to their profound immunosuppression, which enables stable engraftment of human cells and tissues with minimal rejection. Despite their broad utility, these models exhibit unique immunologic and anatomic features and are predisposed to infectious and noninfectious diseases that may confound experimental outcomes and limit translational relevance. This review summarizes current knowledge on spontaneous, infectious, and experimentally induced lesions in NSG and related strains. These mice characteristically display hypoplastic lymphoid organs, including the spleen, thymus, and lymph nodes, due to a near-complete absence of lymphocytes. Spontaneous background lesions include splenic osseous metaplasia, neurodegeneration, pancreatic mastocytosis, cochlear degeneration, intervertebral disk disease, skull hyperostosis, and pancreatic duct cysts, among others. Common spontaneous neoplasms include lymphomas, osteosarcomas, and mammary gland tumors. Due to their immunodeficient status, NSG and NOD-derived mice are also highly susceptible to opportunistic infections, such as Corynebacterium bovis, Chlamydia muridarum, Clostridioides difficile, and mouse kidney parvovirus. In humanized models, engraftment of human immune cells can result in distinctive syndromes, including xenogeneic graft-versus-host disease, post-transplant lymphoproliferative disorders, and chimeric myeloid cell hyperactivation syndrome, which can impact study outcomes and lead to mortality and morbidity. This review is intended as a resource for comparative pathologists to become familiar with these widely used immunodeficient mice, so they can interpret strain-specific lesions and recognize experimental confounders in these mouse models.

The COVID-19 pandemic has increased public reliance on natural treatments, particularly in regions with strong cultural ties to herbal medicine or limited access to conventional healthcare. Globally, surveys have reported heightened use of plant-based remedies and dietary supplements, perceived as safe and effective. In Israel, this trend was evident within an integrative healthcare system that combines conventional and complementary medicine. The public demonstrated significant interest in herbal remedies and supplements to boost immunity and manage pandemic-induced stress. Natural compounds with anti-inflammatory and antiviral properties offer potential pharmacological benefits, warranting clinical investigation. However, restrictive trial criteria hinder broader applicability of findings. To address this gap, we evaluated the effects of bioactive dietary supplements on COVID-19 severity and duration through an online survey. Among respondents, Boswellia emerged as the most popular supplement. Disease duration in Boswellia users was significantly reduced (11.8 +/- 7.1 days) compared to untreated cases or those taking other supplements (18.0 +/- 9.7 days). Known as frankincense, Boswellia's gum resin has traditionally been used for its anti-inflammatory properties. Its bioactive compounds, boswellic acids and incensole acetate, inhibit cytokines like TNF alpha, IL-1 beta, and IL-6, implicated in COVID-19-related cytokine storms and ARDS. Preliminary clinical and laboratory studies suggest Boswellia's potential as an anti-inflammatory and antiviral agent. Laboratory experiments corroborated these findings, demonstrating that cultures infected with 229e virus, as measured by qPCR. Boswellia extracts also decreased viral RNA levels by up to 75% without adverse effects on cell viability and inhibited TMPRSS2 activity, a key protease for viral entry. These findings underscore Boswellia's therapeutic potential, combining anti-inflammatory and antiviral mechanisms, and support further investigation into its use as a complementary treatment for COVID-19.

Climate and land use change have increased human-wildlife interactions, potentially reducing wild species density and prompting behavioral adaptations to urbanized environments. It is still debated if behavioral responses are mainly the result of phenotypic plasticity or if they were driven by anthropic selective pressures, especially in small populations where genetic drift is strong. Our study focused on the small Apennine brown bear population (Ursus arctos marsicanus), which has coexisted with humans in Central Italy for millennia. We characterized genomic diversity and identified adaptation signals distinctive to this population by comparing newly generated and published whole-genome resequencing data from Apennine, Central European, and North American brown bears. Apennine brown bears exhibited reduced genomic diversity, higher inbreeding, and larger realized genetic load compared to other brown bears. We showed that Apennine brown bears possess a unique genomic diversity pattern including selective signatures at genes associated with reduced aggressiveness (eg DCC, SLC13A5). Within these genes, most of the newly discovered variants were located in noncoding regions and some of them were predicted to alter splicing factor binding sites, highlighting the contribution of noncoding variation in shaping complex phenotypes. Our results support the hypothesis that human-induced selection has promoted behavioral changes even in small- and long-isolated populations, reducing conflicts and contributing to the long-term persistence of a large mammal species and its coexistence with humans.

Anthracycline chemotherapy, widely used in cancer treatment, poses a significant risk of cardiotoxicity that results in functional decline. Current diagnostic methods poorly predict cardiotoxicity because they do not detect early damage that precedes dysfunction. Positron emission tomography (PET) is well suited to address this need when coupled with suitable imaging biomarkers. We used PET to evaluate cardiac molecular changes in male C57BL/6J mice exposed to doxorubicin (DOX). These mice initially developed cardiac atrophy, experienced functional deficits within 10 weeks of treatment, and developed cardiac fibrosis by 16 weeks. Elevated cardiac uptake of [68Ga]Ga-FAPI-04, a PET tracer targeting fibroblast activation protein alpha (FAP), was evident by 2 weeks and preceded the onset of functional deficits. Cardiac PET signal correlated with FAP expression and activity as well as other canonical indicators of cardiac remodeling. By contrast, cardiac uptake of [18F]DPA-714 and [18F]MFBG, which target translocator protein 18 kDa and the norepinephrine transporter, respectively, did not differ between the DOX animals and their controls. These findings identify FAP as an early imaging biomarker for DOX-induced cardiac remodeling in males and support the use of FAP PET imaging to detect some cancer patients at risk for treatment-related myocardial damage before cardiac function declines.

Cell movement and division are complex behaviors driven by a dynamic internal cytoskeleton. The molecular components and principles of cytoskeletal assembly are well studied, but less is known about cytoskeletal remodeling events, including how centrioles transition from ciliary base to centrosome. Here, we address this using the chytrid Rhizoclosmatium globosum, a zoosporic fungus that has centrioles and cilia, lost in most fungal lineages. Chytrids undergo reorganization of their microtubule cytoskeleton as they grow from zoospore to multinucleated coenocyte. We use evolutionary comparison, RNA-sequencing, and expansion microscopy to understand this reorganization and further develop this organism as a model for evolutionary cell biology. We find that when motile zoospores transition to sessile sporangia, cilia are retracted into the cytoplasm and degraded, while centrioles detach from the ciliary axoneme yet persist. During the mitotic cycles, short centrioles are associated with a centrosome-like microtubule-organizing center (MTOC) and a dense microtubule array at the spindle pole. After the mitotic cycles, centrioles elongate and form cilia, driven by transcription of genes associated with centriole maturation and ciliogenesis, and microtubule bundles are reorganized. Thus, in chytrids structural remodeling of the centriole is temporally coupled to specific changes in cytoskeletal organization over the coenocytic lifecycle.

Antiretroviral therapy suppresses HIV-1 infection but fails to eliminate a reservoir of intact latent proviruses that reside primarily in CD4+ T cells. The lack of precise understanding of the latent compartment has made it challenging to develop curative strategies for HIV-1 infection. Here we report on the properties of CD4+ T cell clones carrying intact latent proviruses, expanded in vitro from single cells obtained from the reservoir of people living with HIV-1. The latent proviruses in the clones were integrated into ZNF genes, nongenic satellite, and centromeric regions, frequently associated with latency. Despite their descent from single cells, only a fraction of the cells (0.4-14%) expressed relatively low levels of HIV-1 that did not measurably alter host gene transcriptome. Latency-reversing agents (LRAs) variably increased expression, but the effects were modest and clone and LRA specific. The results suggest that pharmacologic and immunologic approaches to clear the reservoir should be optimized to accommodate intra- and inter-clonal diversity.

Clustered regularly interspaced short palindromic repeats (CRISPR)-Cas (CRISPR-associated) systems provide adaptive immunity against phage infection in prokaryotes using an RNA-guided complex that recognizes complementary foreign nucleic acids. Different types of CRISPR-Cas systems have been identified that differ in their mechanism of defense. Upon infection, type III CRISPR-Cas systems employ the Cas10 complex to find phage transcripts and synthesize cyclic oligo-adenylate (cOA) messengers. These ligands bind and activate CARF immune effectors that cause cell toxicity to prevent the completion of the viral lytic cycle. Here, we investigated two proteins containing an N-terminal haloacid dehalogenase (HAD) phosphatase domain followed by four predicted transmembrane helices and a C-terminal CARF domain. We named these proteins Chp for CRISPR-associated HAD phosphatase. We show that, in vivo, Chp localizes to the bacterial membrane and that its activation induces a growth arrest, leads to a depletion of ATP and IMP, and prevents phage propagation during the type III CRISPR-Cas response. In vitro, the CARF domain of Chp binds cyclic tetra-adenylates and the HAD phosphatase domain dephosphorylates dATP, ATP, and IMP. Our findings extend the range of molecular mechanisms employed by CARF effectors to defend prokaryotes against phage infection.