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1. Expanded application to plant reproductive tissues of a branched DNA probe‐based in situ hybridization method

   https://doi.org/10.1002/aps3.70020  

   Anaya, Brooklyn M; Nguyen, Austin T; Matsunaga, Kelly_K S; Hileman, Lena C (August 2025, Applications in Plant Sciences)

   Abstract PremiseDetecting clear tissue‐ and organ‐specific patterns of gene expression is key to understanding the genetic mechanisms that control plant development. In situ hybridization (ISH) of mRNA is one of the most precise, yet most challenging approaches to gene expression assays. Methods and ResultsDetection of histone H4 expression in reproductive tissues ofMimulus lewisii, a model angiosperm, was optimized using the RNAscope ISH assay. The optimized protocol was used to detect histone H4 expression in reproductive tissues of two gymnosperm species,Taxodium distichumandJuniperus virginiana, without further need for species‐specific optimization. Additionally, the optimized protocol was used to detect expression ofCYCLOIDEAtranscription factors inM. lewisiireproductive tissues without further optimization and with results similar to those previously reported. ConclusionsThe RNAscope assay can quickly and sensitively generate high‐quality ISH results in reproductive tissues across a breadth of plant species. 

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2. Gene expression profile analysis of subregions of the adult female reproductive tract in the brown anole, Anolis sagrei

   https://doi.org/10.1530/REP-24-0062  

   Kircher, Bonnie K; Liu, Bin; Bramble, Matthew D; Moses, Malcolm M; Behringer, Richard R (February 2024, Reproduction)

   In briefModes of reproduction across limbed vertebrates are diverse, but the molecular mechanisms required for the development and maintenance of reproductive tract tissue architecture are poorly understood. This paper describes gene expression changes across the regions of the reproductive tract of the adult female brown anole,Anolis sagrei. AbstractThe morphological diversity and functional role of the organs of the female reproductive system across tetrapods (limbed vertebrates) are relatively poorly understood. Although some features are morphologically similar, species-specific modification makes comparisons between species and inference about evolutionary origins challenging. In combination with the study of morphological changes, studying differences in gene expression in the adult reproductive system in diverse species can clarify the function of each organ. Here, we use the brown anole,Anolis sagrei, to study gene expression differences within the reproductive tract of the adult female. We generated gene expression profiles of four biological replicates of the three regions of the female reproductive tract, the infundibulum, glandular uterus, and nonglandular uterus, by RNA-sequencing. We aligned reads to the recently publishedA. sagreigenome and identified significantly differentially expressed genes between the regions using DESeq2. Each organ expressed approximately 14,600 genes, and comparison of gene expression profiles between organs revealed between 367 and 883 differentially expressed genes. We identify shared and region-specific transcriptional signatures for the three regions and compare gene expression in the brown anole reproductive tract to known gene expression patterns in other tetrapods. We find that genes in theHoxcluster have an anterior–posterior, collinear expression pattern as has been described in mammals. We also define a secretome for the glandular uterus. These data provide fundamental information for functional studies of the reproductive tract organs in the brown anole and an important phylogenetic anchor for comparative studies of the evolution of the female reproductive tract. 

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3. Fast and slow-paced reproductive life history across native and invasive populations of a predatory marine snail

   https://doi.org/10.1101/2025.05.15.654356  

   Rugila, Allison L; Bucari, Emily; Rawson, Emma; Schlaug, Amara L; Komoroske, Lisa M; Cheng, Brian S (May 2025, bioRxiv)

   Abstract Populations across a species’ range may be locally adapted, and failure to recognize this variation can lead to inaccurate predictions of their resilience or vulnerability to climate change. Because life history traits are directly linked to fitness, life history theory can serve as a useful framework for evaluating how populations within species may respond to rapid environmental change. However, relatively few studies quantify multiple life history traits and their tradeoffs across many populations, especially in marine taxa. Here, we used a 10-month laboratory experiment to quantify a suite of reproductive traits in populations spanning the strongest latitudinal temperature gradient in the world’s coastal oceans. We examined reproductive traits in wild-captured adults exposed to simulated local conditions for 7 native Atlantic and 4 introduced Pacific populations of the marine predatory gastropodUrosalpinx cinerea. Our data reveals that reproductive season length, the number of reproductive attempts, and annual fecundity unimodally peaked at mid-latitude populations, the species’ range-center. Introduced populations had comparably few spawning attempts and low fecundity despite a longer reproductive period in a less seasonal environment. We then conducted a second experiment quantifying thermal tolerance of developing embryos from 3 native populations, which revealed high sensitivity to temperature at early life stages but weak population differentiation. Taken together, our data reveal stark differences in reproduction that appear to reflect “fast” and “slow” paced lifestyles, which may maximize fitness by spreading the risk of reproductive failure over a single season or lifetime. Our results indicate that warm range-edge populations are highly vulnerable to warming, as low embryonic thermal tolerance may shorten the spawning season and warming is likely to reduce fecundity. This study highlights heterogeneity in life history traits across marine populations that may underlie differential vulnerability to climate warming. Open research statementAll data and code will be publicly available via Figshare and the NSF Biological and Chemical Oceanography Data Management Office (BCO-DMO). 

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4. The period gene alters daily and seasonal timing in Ostrinia nubilalis

   https://doi.org/10.1101/2024.11.02.621642  

   Dayton, Jacob N; Dopman, Erik B (November 2024, bioRxiv)

   Summary The timing of insects’ daily (feeding, movement) and seasonal (diapause, migration) rhythms affects their population dynamics and distribution. Yet, despite their implications for insect conservation and pest management, the genetic mechanisms underlying variation in timing are poorly understood. Prior research in the European corn borer moth (Ostrinia nubilalis) associated ecotype differences in seasonal diapause and daily activity with genetic variation at the circadian clock geneperiod(per). Here, we demonstrate that populations with divergent allele frequencies atperexhibit differences in daily behavior, seasonal development, and the expression of circadian clock genes. Specifically, later daily activity and shortened diapause were associated with a reduction and delay in the abundance of cyclingpermRNA. CRISPR/Cas9-mediated mutagenesis revealed thatperand/or an intact circadian clock network were essential for the appropriate timing of daily behavior and seasonal responsiveness. Furthermore, a reduction ofpergene dosage inperheterozygous mutants (per^-/+) pleiotropically decreased the diapause incidence, shortened post-diapause development, and delayed the timing of daily behavior, in a manner phenotypically reminiscent of wild-type individuals. Altogether, this combination of observational and experimental research strongly suggests thatperis a master regulator of biological rhythms and may contribute to the observed life cycle differences between bivoltine (two generation) and univoltine (one generation)O. nubilalis. HighlightsNatural ecotypes with divergentperiod(per) genotypes differ in their daily and seasonal responses to photoperiodLater daily activity, reduced diapause incidence, and shorter post-diapause development is associated with reducedpermRNA abundanceperis essential for short-day recognition and daily timingReducedpergene dosage shortened post-diapause development and delayed locomotor activity 

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5. Genetic disruption of the baculum compromises the ability of male mice to copulate

   https://doi.org/10.1371/journal.pgen.1011787  

   Ghione, Caleb R; Schultz, Nicholas G; Park, Sungdae; Menke, Douglas B; Dean, Matthew D (July 2025, PLOS Genetics)

   Nerurkar, Nandan (Ed.)

   The baculum, a bone in the penis of many mammal species, shows an astonishing level of morphological divergence between species. Despite hundreds of years of interest, biologists have been unable to directly test its function. The goal of the current study is to uncover molecular details that could allow selective disruption of the baculum while allowing normal sexual differentiation and skeletal development. We compare patterns of androgen receptor binding and single cell gene expression in the developing penis, forelimbs and hindlimbs of mice. We identified chondrocytes in all three tissue types, but those from the developing penis show several unique features, including a population of chondrocytes that express bothRunt-related transcription factor 2(Runx2) andAndrogen receptor(Ar). By combining aRunx2-Cre allele with a floxedArallele in mice, we selectively knocked out androgen signaling in late chondrocytes, resulting in a range of defects in baculum morphology. Males with the most disrupted bacula were unable to copulate, and their bacula appears to be disconnected from the corpus cavernosum muscle. Our study provides insights into the diversity of molecular mechanisms leading to bone and offers the first opportunity to directly test the function of the baculum. 

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