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Background Post-transcriptional control of gene expression mediated by small regulatory RNAs (sRNAs) is vital for growth and development of diverse organisms. The biogenesis of sRNAs is regulated by both positive and negative regulators known to regulate photomorphogenic development. Two microRNAs (miRNAs), miR157 and miR319, also regulate photomorphogenesis. However, genome-wide profiling of sRNAs and their regulation of target genes during photomorphogenesis has been missing. We provide a comprehensive view of sRNA-controlled gene expression in this developmental process. Results By profiling sRNAs and the 5′ ends of degraded mRNAs during the first 24 h of photomorphogenic development in Arabidopsis , we identified 335 sRNA-mediated mRNA cleavage events in de-etiolating seedlings. These cleavage events are primarily resulted from actions of highly expressed miRNAs and irrelevant to the abundance of target mRNAs. In the light, the expression of the slicer protein gene ARGONAUTE1 in the miRNA functioning pathway could be fine-tuned by miRNA168a/b. We also found that miR396a/b positively regulates de-etiolation by suppressing GROWTH REGULATING FACTOR s. Our results suggest that the miRNAs are required to tune down the target mRNAs and regulate photomorphogenesis. Conclusion sRNAs may have a broad impact on gene expression regulation for optimized photomorphogenic development. With both positive and negative regulators under the control of sRNAs, young Arabidopsis seedlings can have a timely but not exaggerated developmental adaptation to light.

The coral-killing sponge, Terpios hoshinota , poses a significant ecological threat to coral reefs, exhibiting rapid expansion and competitive overgrowth. Despite its invasiveness, the genomic basis underlying its adaptability and resilience remains largely unexplored. Here, we present a high-quality genome assembly of T. hoshinota , comprising 169.4 Mb with 40,945 predicted genes. Phylogenomic analysis estimated its divergence from other demosponges during the Ordovician (~ 471 million years ago), even though its simple morphology suggests a more ancient evolutionary origin. Comparative genomic analyses revealed enrichment of genes related to substrate adhesion, innate immunity, and developmental pathways, including expansions of Wnt signaling, homeobox genes, and cell migration gene ontologies which may contribute to its aggressive growth and resilience. Transcriptomic responses under simulated climate stress conditions (heat stress at 31 °C and acidification at 700 ppm pCO₂) indicated dynamic gene regulation, with upregulation of neurotransmitter metabolism, cellular maintenance, and ion homeostasis responses. Despite these stressors, it remained stable. This suggests that T. hoshinota exhibits strong adaptability and resilience through rapid gene regulation. In conclusion, these findings provide molecular insights into T. hoshinota ’s ecological success, its potential expansion under climate change, and its broader impact on coral reef ecosystems.

Leopard complex spotting is a group of white spotting patterns in horses caused by an incompletely dominant gene (LP) where homozygotes (LP/LP) are also affected with congenital stationary night blindness. Previous studies implicated Transient Receptor Potential Cation Channel, Subfamily M, Member 1 (TRPM1) as the best candidate gene for both CSNB and LP. RNA-Seq data pinpointed a 1378 bp insertion in intron 1 of TRPM1 as the potential cause. This insertion, a long terminal repeat (LTR) of an endogenous retrovirus, was completely associated with LP, testing 511 horses (χ(2)=1022.00, p<<0.0005), and CSNB, testing 43 horses (χ(2)=43, p<<0.0005). The LTR was shown to disrupt TRPM1 transcription by premature poly-adenylation. Furthermore, while deleterious transposable element insertions should be quickly selected against the identification of this insertion in three ancient DNA samples suggests it has been maintained in the horse gene pool for at least 17,000 years. This study represents the first description of an LTR insertion being associated with both a pigmentation phenotype and an eye disorder.

Substantial climate changes are evident across Australia, with declining rainfall and rising temperature in conjunction with frequent fires. Considerable species loss and range contractions have been predicted; however, our understanding of how genetic variation may promote adaptation in response to climate change remains uncertain. Here we characterized candidate genes associated with rainfall gradients, temperatures and fire intervals through environmental association analysis. We found that overall population adaptive genetic variation was significantly affected by shortened fire intervals, whereas declining rainfall and rising temperature did not have a detectable influence. Candidate SNPs associated with rainfall and high temperature were diverse, whereas SNPs associated with specific fire intervals were mainly fixed in one allele. Gene annotation further revealed four genes with functions in stress tolerance, the regulation of stomatal opening and closure, energy use and morphogenesis with adaptation to climate and fire intervals. B. attenuata may tolerate further changes in rainfall and temperature through evolutionary adaptations based on their adaptive genetic variation. However, the capacity to survive future climate change may be compromised by changes in the fire regime.

Seed size is a key functional trait that affects plant fitness at the seedling stage and may vary greatly with species fruit size, growth form and fecundity. Using structural equation modelling (SEM) and correlated trait evolution analysis, we investigated the interaction network between seed size and fecundity, postfire regeneration strategy, fruit size, plant height and serotiny (on-plant seed storage) among 82 species of the woody shrub genus, Hakea, with a wide spectrum of seed sizes (2-500 mg). Seed size is negatively correlated with fecundity, while fire-killed species (nonsprouters) produce more seeds than resprouters though they are of similar size. Seed size is unrelated to plant height and level of serotiny while it scales allometrically with fruit size. A strong phylogenetic signal in seed size revealed phylogenetic constraints on seed size variation in Hakea. Our analyses suggest a causal relationship between seed size, fecundity and postfire regeneration strategy in Hakea. These results demonstrate that fruit size, fecundity and evolutionary history have had most control over seed size variation among Hakea species.

Coral skeletons constitute sources of nutrients and energy for holobiont. Although bacteria predominate in endolithic microbiomes of corals, their ecological functions have long been masked by those of symbiotic microalgae. In the skeleton of Isopora palifera, previous studies showed the absence of microalgae and a green layer dominated by green sulfur bacteria. This system, which excludes a contribution from microalgae, provides a perfect model for studying the role of endolithic bacteria in corals. Using this model, we examined the metabolite profile and translocation of organic matter between coral tissue and skeleton. Chromatography-time-of-flight-mass spectrometry and ultra-high-performance liquid chromatography tandem mass spectrometry revealed distinct metabolic profiles in tissue and different skeletal layers. A stable isotope incubation experiment further demonstrated 13C translocation between tissue and the green layer, but no translocation of 15N. These findings suggest communication between the two compartments that is generally carbon-based, possibly in the form of carbohydrates and bioactive compounds, such as corticosterone and domoic acid. Nevertheless, some nitrogenous compounds appear to have an endolithic source, indicating a possible contribution of the skeleton to coral animal. Notably, antibiotic treatment greatly increased 15N translocation in the tissue but not in the green layer. This highlights an important role of bacteria in nitrogen cycling in the holobiont and in establishing the nitrogen-limiting green layer. Altogether, this study provides the first data about coral skeletal metabolomes. Based on these findings, we propose a model of interactions between coral animal and skeletal bacterial communities, offering a new perspective on the ecological role of endolithic bacteria in corals.

Currently the origin and trajectories of novel traits are emphasised in evolutionary studies, the role of stabilization is neglected, and interpretations are often post hoc rather than as hypothesised responses to stated agents of selection. Here we evaluated the impact of changing environmental conditions on trait evolution and stabilization and their relative contribution to diversification in a prominent Australian genus, Hakea (Proteaceae). We assembled a time-based phylogeny for Hakea, reconstructed its ancestral traits for six attributes and determined their evolutionary trajectories in response to the advent or increasing presence of fire, seasonality, aridity, nectar-feeding birds and (in)vertebrate herbivores/granivores. The ancestral Hakea arose 18 million years ago (Ma) and was broad-leaved, non-spinescent, insect-pollinated, had medium-sized, serotinous fruits and resprouted after fire. Of the 190 diversification events that yielded the 82 extant species analysed, 850% involved evolution, stabilization or re-evolution (reversal) of individual novel traits. Needle leaves appeared 14 Ma and increased through the Neogene/Quaternary coinciding with intensifying seasonality and aridity. Spinescence arose 12 Ma consistent with the advent of vertebrate herbivores. Bird-pollination appeared 14 Ma in response to advent of the Meliphagidae in the early Miocene. Small and large woody fruits evolved from 12 Ma as alternative defenses against granivory. Fire-caused death evolved 14 Ma, accounting for 50% of subsequent events, as fire became less stochastic. Loss of serotiny began in the late Miocene as non-fireprone habitats became available but only contributed 8% of events. Innovation and subsequent stabilization of functional traits promoted the overall species diversification rate in Hakea by 15 times such that only three species now retain the ancestral phenotype. Our approach holds great promise for understanding the processes responsible for speciation of organisms when the ancestral condition can be identified and the likely selective agents are understood.

Land-locked meromictic lakes are characterized by long-term stratification and steep redox gradients that sustain vertically structured microbial communities and tightly coupled biogeochemical processes. Because complete overturns of the lake are rare, the dynamics of microbial reassembly after redox gradients collapse and subsequently recover remain poorly resolved. We investigated a mixing restratification transition in Lake Shira (Siberia) with depth-stratified sampling of oxic, chemocline, anoxic, and water sediment interface layers across four stages: intermittent holomictic (IH), complete holomictic (CH), developing meromictic (DM), and stable meromictic (M). 16S rRNA gene amplicons showed that CH homogenized the water column, dominated by Gamma- and Alphaproteobacteria, Campylobacteria, and Cyanobacteriia. As stratification re-formed (DM to M), communities became strongly depth-partitioned, with Desulfobacterota and other anaerobes re-established in sulfidic deep waters and assemblages concentrating near the redox transition. Nanopore metagenomics reconstructed 401 MAGs, revealing stage- and depth-specific functional repertoires consistent with redox zonation. Core MAGs, including Yoonia spp., persisted across phases, suggesting functional continuity underpinning rapid ecosystem recovery. These data provide a system-wide view of biogeochemical reassembly during collapse and restoration of stratification meromictic lake.Competing Interest StatementThe authors have declared no competing interest.Funder Information DeclaredNational Science and Technology Council, NSTC 113-2611-M-031-001, NSTC 114-2611-M-031-001, MOST 110-2923-B-001-004-MY3, MOST 106-2923-B-001-003-MY3The Ministry of Education and Science of the Russian Federation, FWES-2024-0024)

Phages are important symbionts in corals that modulate the community and functions of other symbiotic bacteria. Although phages infecting coral pathogens have been reported, no phage targeting beneficial microorganisms in corals has been isolated to date. From seawater near Acropora and Stylophora corals, we isolated the first bacteriophages (designated EmPhiA and EmPhiS) that infect Endozoicomonas montiporae CL-33, a model strain of the coral-prevalent and predominant Endozoicomonas bacteria. Electron microscopic observations of both phages showed Myovirus-like morphology and head sizes characteristic of jumbophages, with cryo-electron microscopy reveals long whiskers unprecedent in known phages. Genetically, these phages shared 99.21% genome similarity and are distant from known prokaryotic viruses, suggesting that they represent a novel viral species, which we name Encorevirus taiwanensis, in a novel family Encoreviridae. The small burst sizes of these phages (13.14 PFU/cell for EmPhiA and 21.4 PFU/cell for EmPhiS) potentially enable continuous coexistence of them with host bacteria within corals, making them putative core members of coral holobionts. Furthermore, host range test showed that EmPhiA and EmPhiS infect both Endozoicomonas bacteria isolated from stony and soft corals, implying their presence in a broad spectrum of host marine invertebrates. Using EmPhiS, we also investigated phage-bacterium interaction during its infection of E. montiporae CL-33. Interestingly, in addition to modulation of host cellular machinery, we found expression of several tellurium resistance proteins by EmPhiS during infection, which may provide the host additional stress resistance. These phages provide a novel model that will greatly advance our understanding of coral-Endozoicomonas-phage interactions.

PurposeOne of the key approaches to minimize the risk of COVID-19 transmission would be to reduce the titres of SARS-CoV-2 in the saliva of infected COVID-19 patients. This is particularly important in high-risk procedures like dental treatment. The present randomized control trial evaluated the efficacy of three commercial mouth-rinse viz. povidone–iodine (PI), chlorhexidine gluconate (CHX) and cetylpyridinium chloride (CPC), in reducing the salivary SARS-CoV-2 viral load in COVID-19 patients compared with water.MethodsA total of 36 SARS-CoV-2-positive patients were recruited, of which 16 patients were randomly assigned to four groups—PI group (n = 4), CHX group (n = 6), CPC group (n = 4) and water as control group (n = 2). Saliva samples were collected from all patients at baseline and at 5 min, 3 h and 6 h post-application of mouth-rinses/water. The samples were subjected to SARS-CoV-2 RT-PCR analysis.ResultsComparison of salivary Ct values of patients within each group of PI, CHX, CPC and water at 5 min, 3 h and 6 h time points did not show any significant differences. However, when the Ct value fold change of each of the mouth-rinse group patients were compared with the fold change of water group patients at the respective time points, a significant increase was observed in the CPC group patients at 5 min and 6 h and in the PI group patients at 6 h.ConclusionThe effect of decreasing salivary load with CPC and PI mouth-rinsing was observed to be sustained at 6 h time point. Within the limitation of the current study, as number of the samples analyzed, the use of CPC and PI formulated that commercial mouth-rinses may be useful as a pre-procedural rinse to help reduce the transmission of COVID-19.ISRCTN (ISRCTN95933274), 09/09/20, retrospectively registered