The rockefeller university

BackgroundRed mullet (Mullus barbatus) is a key species in Mediterranean fisheries, yet its stock structure and population dynamics remain poorly understood due to a lack of comprehensive genomic resources. This study provides the first high-quality reference genome for M. barbatus and a comprehensive set of SNP markers to investigate its population structure and adaptive potential across the Mediterranean.ResultsUsing the newly generated chromosome-level reference genome, we re-analyzed a Mediterranean-wide reduced-representation genomic dataset. Our analysis reveals a panmictic population structure with strong genetic connectivity across the species' range, likely driven by extensive larval dispersal and multigenerational gene flow. Despite minimal genome-wide differentiation, outlier analysis identified candidate loci under directional selection, linked to key biological processes such as ontogeny and environmental adaptation.ConclusionsThis study presents the first genomic resource for M. barbatus, providing valuable insights into its genetic structure and adaptive mechanisms. While the identification of loci under selection offers promising leads, these findings are preliminary due to the limited genomic coverage of the dataset. Nonetheless, they pave the way for future genomic studies to explore how M. barbatus adapts to environmental and anthropogenic pressures. These results hold significant implications for the sustainable management of Mediterranean fisheries, especially in the context of climate change and conservation.

Juvenile hormones (JH) regulate insect development, reproduction, and behavior. The JH analog Methoprene, widely used in pest control, disrupts these processes by inhibiting maturation rather than causing mortality. Beyond its physiological effects, Methoprene influences insect behavior, including mate choice, social organization, and foraging, by altering neuronal sensitivity and gene expression via the Methoprene-tolerant receptor. These behavioral disruptions may negatively impact insect populations, including pollinators like honeybees. While laboratory studies highlight Methoprene's behavioral consequences, field research is needed to assess its ecological effects. Understanding these broader impacts is crucial for evaluating the risks associated with JH-based pest control strategies.

CD40 agonism enhances antitumor immunity but is limited by systemic toxicity and poor efficacy. Here, we present a phase 1 study (NCT04059588) of intratumoral (i.t.) 2141-V11, an Fc-engineered anti-CD40 agonistic antibody with enhanced binding to the inhibitory receptor Fc gamma RIIB. Among 12 metastatic cancer patients, 2141-V11 was well tolerated without dose-limiting toxicities. Six patients experienced tumor reduction, including two complete responses in melanoma and breast cancer. 2141-V11 induced regression in injected and non-injected lesions, correlating with systemic CD8+T cell activation and mature tertiary lymphoid structures (TLSs) in complete responders. In CD40/Fc gamma Rs humanized mice bearing orthotopic tumors, i.t. 2141-V11 promoted de novo TLS formation, facilitating i.t. CD8+ T cell effector responses independent of lymph node priming. The resulting local immune responses by 2141-V11 mediated abscopal antitumor effects and sustained immune memory. These findings demonstrate that i.t. 2141-V11 is safe and promotes immune-privileged tumor microenvironments that promote systemic and durable antitumor immunity.

Communication is crucial to social life, and in ants, it is mediated primarily through olfaction. Ants have more odorant receptor (OR) genes than any other group of insects, generated through tandem duplications that produce large genomic arrays of related genes. The mechanism by which olfactory sensory neurons (OSNs) produce a single functional OR from these arrays remains unclear. In ant OSNs, only mRNA from one OR in an array is exported into the cytoplasm, while upstream genes are silent and transcripts from downstream genes remain nuclear. Here, we show that readthrough transcription in the downstream direction generates non-translated transcripts. We also find that OR promoters are bidirectional, producing anti-sense long non-coding RNAs. We suspect that neither readthrough nor antisense transcription produces functional RNA but that bidirectional transcription alone is critical to suppressing the expression of all other OR genes in a tandem array. Finally, we present evidence that this regulatory architecture is conserved across ants and bees, suggesting that this mechanism for functionally monogenic OR expression is widespread in insects with expanded OR repertoires.

The cellular basis of COVID-19 severity in patients with deficiencies in type I IFN immunity remains unclear. In this study, we differentiated cardiomyocytes and macrophages from IFNAR1 competent (IFNAR1comp) and deficient (IFNAR1def) induced pluripotent stem cells (iPSCs), and analyzed virus replication and cytokine production after exposure to SARS-CoV-2. Cardiomyocytes expressed the SARS-CoV-2 receptor angiotensin-converting enzyme 2 (ACE2) and showed abundant SARS-CoV-2 replication, which was higher in IFNAR1def than IFNAR1comp cells. Treatment with exogenous IFN alpha mitigated infection in IFNAR1comp, but not in IFNAR1def cardiomyocytes. In contrast, macrophages did not express ACE2 and did not support SARS-CoV-2 replication, but produced pro-inflammatory cytokines upon virus exposure, which was impaired in IFNAR1def macrophages. In conclusion, type I IFNs decrease SARS-CoV-2 replication in human iPSC-derived cardiomyocytes, while they increase cytokine responses of macrophages.

Zika virus (ZIKV) is an emerging arbovirus, and its infection is often asymptomatic or mild; however, it can lead to severe neurological disorders. Currently, there are no approved treatments or vaccines for ZIKV, highlighting the urgent need to explore potential therapeutic options. In this study, we evaluated the antiviral activity of a novel synthetic peptide (GA-peptide) against ZIKV in vitro. The GA-peptide exhibited dose-dependent inhibition of the virus, affecting multiple stages of the ZIKV replication cycle. It demonstrated virucidal activity and effectively protected Vero cells from ZIKV infection. Additionally, the GA-peptide disrupted viral entry by targeting both the attachment and internalization phases, as well as post-entry stages of the infection. In silico analyses identified potential viral targets that interact with the GA-peptide. These findings underscore the GApeptide's promising potential as a therapeutic agent against ZIKV and its relevance in the development of new antiviral drugs.

Measurements of the production yields of charm baryons (Lambda(+)(c)) and charm mesons (D-0) in proton-lead collisions at a nucleon-nucleon center-of-mass energy of 8.16 TeV are presented. The data were collected in 2016 with the CMS experiment and correspond to an integrated luminosity of 186 nb(-1). The Lambda(+)(c) baryon is reconstructed from the decay channel Lambda(+)(c) -> K(S)(0)p, while the D-0 meson is reconstructed via D-0 -> K- pi(+). The Lambda(+)(c) baryon and D-0 meson yields are extracted in several charged-particle multiplicity classes. No strong multiplicity dependence of the Lambda(+)(c) -to-D-0 yield ratio is observed, unlike the observed strange baryon to strange meson yield ratio of Lambda/(Lambda) over bar to K-S(0), which shows a strong multiplicity dependence. This observation indicates different mechanisms for the multiplicity evolution of hadronization processes for charm and strange quarks and provides new constraints to the understanding of heavy flavor production and collectivity in small collision systems.