Haploid Genome Research Articles

Detection of Bombyx mori as a Protein Source in Feedingstuffs by Real-Time PCR with a Single-Copy Gene Target

The silkworm, Bombyx mori, is reared on a large scale, mainly for silk production. The waste from this silk production, like pupae, is underused. As an edible insect, B. mori is a good source of protein in human food and animal feed. In recent years, European legislation on the use of insects has evolved and a multitude of European companies have initiated the rearing of insects specifically for food and feed applications. Regarding animal feed, Commission Regulations (EU) 2021/1372 and 2021/1925 authorize eight insect species, including silkworm, as processed animal proteins for use in fish, pig, and poultry feed. The incorporation of edible insects into the human diet falls within Regulation (EU) No. 2015/2283 concerning novel foods. Implementation of authentication methods is imperative to ensure the conformity of the products. In the present study, we propose a specific real-time PCR method for the detection of silkworm (B. mori). The developed PCR test amplifies a 98 bp fragment of the cadherin gene. This gene is present in a single-copy per haploid genome, as demonstrated by experimental evidence. The qualitative method was successfully evaluated on the performance criteria of specificity, sensitivity, efficiency, robustness, and transferability. The applicability of the test was assessed on samples of B. mori from industry. Light microscopy and DNA metabarcoding approaches were used as a complement to genomic analysis as a means of providing authentication of the samples.

FindGSEP: Estimating genome size of polyploid species using k-mer frequencies.

estimating genome size using k-mer frequencies, which plays a fundamental role in designing genome sequencing and analysis projects, has remained challenging for polyploid species, i.e., ploidy p > 2. To address this, we introduce findGSEP, which is designed based on iterative curve fitting of k-mer frequencies. Precisely, it firstly disentangles up to p normal distributions by analyzing k-mer frequencies in whole genome sequencing of the focal species. Secondly, it computes the sizes of genomic regions related to 1∼p (homologous) chromosome(s) using each respective curve fitting, from which it infers the full polyploid and average haploid genome size. findGSEP can handle any level of ploidy p, and infer more accurate genome size than other well-known tools, as shown by tests using simulated and real genomic sequencing data of various species including octoploids. findGSEP was implemented as a web server, which is freely available at http://146.56.237.198:3838/findGSEP/. Also, findGSEP was implemented as an R package for parallel processing of multiple samples. Source code and tutorial on its installation and usage is available at https://github.com/sperfu/findGSEP. Supplementary data are available at Bioinformatics online.

Geometric deep learning framework for de novo genome assembly.

The critical stage of every de novo genome assembler is identifying paths in assembly graphs that correspond to the reconstructed genomic sequences. The existing algorithmic methods struggle with this, primarily due to repetitive regions causing complex graph tangles, leading to fragmented assemblies. Here, we introduce GNNome, a framework for path identification based on geometric deep learning that enables training models on assembly graphs without relying on existing assembly strategies. By leveraging only the symmetries inherent to the problem, GNNome reconstructs assemblies from PacBio HiFi reads with contiguity and quality comparable to those of the state-of-the-art tools across several species. With every new genome assembled telomere-to-telomere, the amount of reliable training data at our disposal increases. Combining the straightforward generation of abundant simulated data for diverse genomic structures with the AI approach makes the proposed framework a plausible cornerstone for future work on reconstructing complex genomes with different ploidy and aneuploidy degrees. To facilitate such developments, we make the framework and the best-performing model publicly available, provided as a tool that can directly be used to assemble new haploid genomes.

The genome and comparative transcriptome of the euryhaline model ciliate Paramecium duboscqui reveal adaptations to environmental salinity

BackgroundAs a potential model organism for studies of environmental and cell biology, Paramecium duboscqui is a special euryhaline species of Paramecium that can be found in fresh, brackish, or marine water in natural salinity ranges between 0‰ and 33‰. However, the genome information as well as molecular mechanisms that account for its remarkable halotolerant traits remain extremely unknown. To characterize its genome feature, we combined PacBio and Illumina sequencing to assemble the first high-quality and near-complete macronuclear genome of P. duboscqui. Meanwhile, comparative transcriptomic profiles under different salinities gave underlying insight into the molecular mechanism of its adaptations to environmental salinity.ResultsThe results showed that the MAC genome of P. duboscqui comprises 160 contigs, with 113 of them possessing telomere (~ 28.82 Mb haploid genome size). Through comparative genomic analyses with the other ciliate, we found that gene families encoding transmembrane transporter proteins have been expanded in P. duboscqui, showing enormous potential in salinity adaptation. Like other Paramecium, P. duboscqui utilizes TGA as its only termination codon and has reassigned TAA and TAG to encode glutamine. P. duboscqui showed different growth rates under different salinities, with an optimum growth rate in 5‰ salinity. A comparison of the transcriptomic profiles among P. duboscqui grown under different concentrations showed that genes involved in protein folding, oxygen respiration, and glutathione-dependent detoxification were upregulated in the high-salt group, whereas genes encoding DNA-binding proteins and transcription factors were upregulated in the low-salt group, suggesting distinct mechanisms for responding to low and high salinity. Weighted gene coexpression network analysis (WGCNA) linked the hub genes expressed at 30‰ salinity to cysteine-type peptidase activity, lipid transfer, sodium hydrogen exchange, and cell division, with the hub genes expressed at 0‰ salinity involved in transmembrane transport and protein localization.ConclusionsThis study characterizes a new euryhaline model Paramecium, provides novel insights into Paramecium evolution, and describes the molecular mechanisms that have allow P. duboscqui to adapt to different osmotic environments.

Reference-based genome assembly and comparative genomics of Calamus Brandisii Becc. for unveiling sex-specific genes for early gender detection.

Calamus brandisii Becc. is an endangered rattan species indigenous to the Western Ghats of India and used in the furniture and handicraft industries. However, its dioecious nature and longer flowering time pose challenges for conservation efforts. Developing markers for early gender detection in seedlings is crucial for maintaining viable populations for in-situ and ex-situ conservation. Currently, no sex chromosomes or gender-specific genes have been reported in the species. We report the first comprehensive comparative genomics study between the male and female genomes of C. brandisii to identify polymorphisms and potential genes for gender determination. Reference-based assembly was conducted and the male and female genomes were predicted to contain 43,810 and 50,493 protein-coding genes respectively. The haploid genome size was ∼691Mb and ∼884Mb for male and female genomes respectively. Comparative analysis revealed significant genetic variation between the two genomes including 619,776 SNPs, 73,659 InDels, 212,123 Structural variants (SVs) and 305 copy number variations (CNVs). A total of 5 male-specific and 11 female-specific genes linked to the sex determining region was predicted. The genomic variants identified between the two genomes could be used in development of markers for early gender identification in C. brandisii for restoration programs. The gender-specific genes identified in this study also provide new insights into the mechanisms of sex determination and differentiation in rattans.

A haplotype-resolved genome assembly of Coptis teeta, an endangered plant of significant medicinal value

Coptis teeta Wall. (Ranunculaceae), an endangered plant species of significant medicinal value, predominantly undergoes clonal propagation, potentially compromising the species’ evolutionary potential and ultimately increase its risk of extinction. In this study, we successfully assembled two sets of haploid genomes (Hap1 and Hap2) for C. teeta, comprising nine homologous chromosome pairs, by employing Illumina and PacBio sequencing technologies. The genome annotation identified a total of 43,979 and 46,311 protein-coding genes in Hap1 and in Hap2, and most of them were functionally annotated. The high-quality reference genome will serve as an indispensable genomic resource for conservation and comprehensive exploitation of this endangered species. Between the two haploid genomes, numerous structural alterations were detected within the nine homologous chromosome pairs, potentially resulting in aberrant synapsis and irregular chromosomal segregation and thus contributing to the sustained preservation of clonal propagation in C. teeta. The findings offer new perspective for elucidating the genetic mechanism underlying the compromised sexual reproductive capacity of C. teeta, thereby facilitating its enhancement though molecular breeding and genetic improvement.

Chromosomal-level reference genome assembly of muskox (Ovibos moschatus) from Banks Island in the Canadian Arctic, a resource for conservation genomics

The muskox (Ovibos moschatus), an integral component and iconic symbol of arctic biocultural diversity, is under threat by rapid environmental disruptions from climate change. We report a chromosomal-level haploid genome assembly of a muskox from Banks Island in the Canadian Arctic Archipelago. The assembly has a contig N50 of 44.7 Mbp, a scaffold N50 of 112.3 Mbp, a complete representation (100%) of the BUSCO v5.2.2 set of 9225 mammalian marker genes and is anchored to the 24 chromosomes of the muskox. Tabulation of heterozygous single nucleotide variants in our specimen revealed a very low level of genetic diversity, which is consistent with recent reports of the muskox having the lowest genome-wide heterozygosity among the ungulates. While muskox populations are currently showing no overt signs of inbreeding depression, environmental disruptions are expected to strain the genomic resilience of the species. One notable impact of rapid climate change in the Arctic is the spread of emerging infectious and parasitic diseases in the muskox, as exemplified by the range expansion of muskox lungworms, and the recent fatal outbreaks of Erysipelothrix rhusiopathiae, a pathogen normally associated with domestic swine and poultry. As a genomics resource for conservation management of the muskox against existing and emerging disease modalities, we annotated the genes of the major histocompatibility complex on chromosome 2 and performed an initial assessment of the genetic diversity of this complex. This resource is further supported by the annotation of the principal genes of the innate immunity system, genes that are rapidly evolving and under positive selection in the muskox, genes associated with environmental adaptations, and the genes associated with socioeconomic benefits for Arctic communities such as wool (qiviut) attributes. These annotations will benefit muskox management and conservation.

Genomics resources for the Rapa Nui (Eastern Island) spiny lobster Panulirus pascuensis (Crustacea: Decapoda: Achelata)

BackgroundThe Easter Island spiny lobster Panulirus pascuensis (Reed, 1954) or ‘Ura’ in the Rapa Nui language, is a little known species native to the south eastern Pacific Ocean, distributed along the coasts of Easter Island, Pitcairn Island, and the Salas y Gómez Ridge. In Easter Island, P. pascuensis is the target of a small and profitable and probably overexploited fishery. In this study, we profited from a series of bioinformatic analyses to mine biological insight from low-pass short-read next generation sequencing datasets; we have estimated genome size and ploidy in P. pascuensis using a k-mer strategy, discovered, annotated, and quantified mobile elements in the nuclear genome, assembled the 45S rRNA nuclear DNA cassette and mitochondrial chromosome, and explored the phylogenetic position of P. pascuensis within the genus Panulirus using the signal retrieved from translated mitochondrial protein coding genes.ResultsK-mer analyses predicted P. pascuensis to be diploid with a haploid genome size ranging between 2.75 Gbp (with k-mer = 51) and 3.39 Gbp (with k-mer = 18). In P. pascuensis, repetitive elements comprise at least a half and a maximum of three fourths of the nuclear genome. Almost a third (64.94%) of the repetitive elements present in the studied nuclear genome were not assigned to any known family of transposable elements. Taking into consideration only annotated repetitive elements, the most abundant were classified as Long Interspersed Nuclear Elements (22.81%). Less common repetitive elements included Long Terminal Repeats (2.88%), Satellite DNA (2.66%), and DNA transposons (2.45%), among a few others. The 45S rRNA DNA cassette of P. pascuensis was partially assembled into two contigs. One contig, 2,226 bp long, encoded a partially assembled 5′ ETS the entire ssrDNA (1,861 bp), and a partial ITS1. A second contig, 6,714 bp long, encoded a partially assembled ITS1, the entire 5.8S rDNA (158 bp), the entire ITS2, the entire lsrDNA (4,938 bp), and a partial 3′ ETS (549 bp). The mitochondrial genome of P. pascuensis was 15,613 bp long and contained 13 protein-coding genes (PCGs), 22 transfer RNA (tRNA) genes, and two ribosomal RNA genes (12S ribosomal RNA [rrnS] and 16S ribosomal RNA [rrnL]). A phylomitogenomic analysis based on PCGs retrieved Panulirus pascuensis as sister to a fully supported clade comprising P. cygnus and P. longipes.ConclusionWe expect that the information generated in this study will guide the assembly of a chromosome-level nuclear genome for P. pascuensis in the near future. The newly assembled 45S rRNA nuclear DNA cassette and mitochondrial chromosome can support bioprospecting and biomonitoring of P. pascuensis using environmental DNA. The same elements can help to survey the public market place and detect mislabelling of this and other spiny lobsters. Overall, the genomic resources generated in this study will aid in supporting fisheries management and conservation strategies in this iconic spiny lobster that is likely experiencing overexploitation.

A Draft Pacific Ancestry Pangenome Reference.

Individuals of Pacific ancestry suffer some of the highest rates of health disparities yet remain vastly underrepresented in genomic research, including currently available linear and pangenome references. To begin addressing this, we developed the first Pacific ancestry pangenome reference using 23 individuals with diverse Pacific ancestry. We assembled 46 haploid genomes from these 23 individuals, resulting in highly accurate and contiguous genome assemblies with an average quality value of 55.0 and an average N50 of 40.7 Mb, marking the first de novo assembly of highly accurate Pacific ancestry genomes. We combined these assemblies to create a pangenome reference, which added 30.6 Mb of novel sequence missing from the Human Pangenome Reference Consortium (HPRC) reference. Mapping short reads to this pangenome reduced variant call errors and yielded more true-positive variants compared to the HPRC and T2T-CHM13 references. This Pacific ancestry pangenome reference serves as a resource to enhance genetic analyses for this underserved population.

Chromosome-level and haplotype-resolved genome assembly of Dracaena cambodiana (Asparagaceae)

Dracaena cambodiana Pierre ex Gagn. (Asparagaceae) is the source plant of Dragon’s blood and has high ornamental values in gardening. Currently, this species is classified as the second-class state-protected species in the National Key Protected Wild Plants (NKPWP) of China. However, limited genomic data has hindered a more comprehensive scientific understanding of the processes involved in the production of Dragon’s blood and the related conservation genomics research. In this study, we assembled a haplotype-resolved genome of D. cambodiana. The haploid genomes, haplotype A and haplotype B, are 1,015.22 Mb and 1,003.13 Mb in size, respectively. The completeness of haplotype A and haplotype B genomes was 98.60% and 98.20%, respectively, using the “embryophyta_10” dataset. Haplotype A and haplotype B genomes contained 27,361 and 27,066 protein-coding genes, respectively, with nearly all being functionally annotated. These findings provide new insights into the genomic characteristics of D. cambodiana and will offer additional genomic resources for studying the biosynthesis mechanism of Dragon’s blood and the horticultural application of Dragon trees.

Chromosome-level genome assembly and annotation of Flueggea virosa (Phyllanthaceae)

Flueggea virosa (Roxb. ex Willd.) Royle, an evergreen shrub and small tree in the Phyllanthaceae family, holds significant potential in garden landscaping and pharmacological applications. However, the lack of genomic data has hindered further scientific understanding of its horticultural and medicinal values. In this study, we have assembled a haplotype-resolved genome of F. virosa for the first time. The two haploid genomes, named haplotype A genome and haplotype B genome, are 487.33 Mb and 477.53 Mb in size, respectively, with contig N50 lengths of 31.45 Mb and 32.81 Mb. More than 99% of the assembled sequences were anchored to 13 pairs of pseudo-chromosomes. Furthermore, 21,587 and 21,533 protein-coding genes were predicted in haplotype A and haplotype B genomes, respectively. The availability of this chromosome-level genome fills the gap in genomic data for F. virosa and provides valuable resources for molecular studies of this species, supporting future research on speciation, functional genomics, and comparative genomics within the Phyllanthaceae family.

Prospects for combining the methods of haploid biotechnology and genome editing to improve spiked grains of the <i>Triticeae</i> family (review)

Over the past few decades, haploid biotechnologies have become an integral part of breeding programs for many crops. Using the strategy of doubling haploids induced in the culture of gametic cells and tissues in vitro, through androgenesis, gynogenesis and distant hybridization, it became possible to significantly reduce the time for developing new varieties. Using the technology of doubled haploids, within one or two generations, it is possible to obtain aligned homozygous lines, which can both help speed up the breeding process and study several scientific and practical issues. Another promising tool for developing lines and samples with specified traits within several generations is genome editing (engineering) using various nuclease-based engineering complexes. The CRISPR/Cas9 genome editing technology, which came into use ten years ago, allows solving a wide variety of problems in plant functional genomics, including engineering resistance to biotic and abiotic stresses, improving productivity and product quality. The technology is better than the most known methods for improving varieties for the traits which have mono- or polygenic control, since it allows changing several genes simultaneously, which is important for polyploid species. An integral part of plant genome editing, as well as haploidogenesis technologies, is cell and tissue culture in vitro, which gives possibility for their combination. The combination of technologies allows producing homozygous plants with new gene-specific mutations, which improves genetic diversity and accelerates the selection of linear material with new economically valuable traits. The current review has summarized the experience of combining haploidy and genome editing methods in spiked grains of the Triticeae family. In addition to analyzing the current state, there have been considered the prospects for further development of technologies for obtaining haploids of wheat, barley, triticale, and rye with an edited genome.

ProcaryaSV: structural variation detection pipeline for bacterial genomes using short-read sequencing

BackgroundStructural variations play an important role in bacterial genomes. They can mediate genome adaptation quickly in response to the external environment and thus can also play a role in antibiotic resistance. The detection of structural variations in bacteria is challenging, and the recognition of even small rearrangements can be important. Even though most detection tools are aimed at and benchmarked on eukaryotic genomes, they can also be used on prokaryotic genomes. The key features of detection are the ability to detect small rearrangements and support haploid genomes. Because of the limiting performance of a single detection tool, combining the detection abilities of multiple tools can lead to more robust results. There are already available workflows for structural variation detection for long-reads technologies and for the detection of single-nucleotide variation and indels, both aimed at bacteria. Yet we are unaware of structural variations detection workflows for the short-reads sequencing platform. Motivated by this gap we created our workflow. Further, we were interested in increasing the detection performance and providing more robust results.ResultsWe developed an open-source bioinformatics pipeline, ProcaryaSV, for the detection of structural variations in bacterial isolates from paired-end short sequencing reads. Multiple tools, starting with quality control and trimming of sequencing data, alignment to the reference genome, and multiple structural variation detection tools, are integrated. All the partial results are then processed and merged with an in-house merging algorithm. Compared with a single detection approach, ProcaryaSV has improved detection performance and is a reproducible easy-to-use tool.ConclusionsThe ProcaryaSV pipeline provides an integrative approach to structural variation detection from paired-end next-generation sequencing of bacterial samples. It can be easily installed and used on Linux machines. It is publicly available on GitHub at https://github.com/robinjugas/ProcaryaSV.

Advanced Protocol for Molecular Characterization of Viral Genome in Fission Yeast (Schizosaccharomyces pombe).

Fission yeast, a single-cell eukaryotic organism, shares many fundamental cellular processes with higher eukaryotes, including gene transcription and regulation, cell cycle regulation, vesicular transport and membrane trafficking, and cell death resulting from the cellular stress response. As a result, fission yeast has proven to be a versatile model organism for studying human physiology and diseases such as cell cycle dysregulation and cancer, as well as autophagy and neurodegenerative diseases like Alzheimer's, Parkinson's, and Huntington's diseases. Given that viruses are obligate intracellular parasites that rely on host cellular machinery to replicate and produce, fission yeast could serve as a surrogate to identify viral proteins that affect host cellular processes. This approach could facilitate the study of virus-host interactions and help identify potential viral targets for antiviral therapy. Using fission yeast for functional characterization of viral genomes offers several advantages, including a well-characterized and haploid genome, robustness, cost-effectiveness, ease of maintenance, and rapid doubling time. Therefore, fission yeast emerges as a valuable surrogate system for rapid and comprehensive functional characterization of viral proteins, aiding in the identification of therapeutic antiviral targets or viral proteins that impact highly conserved host cellular functions with significant virologic implications. Importantly, this approach has a proven track record of success in studying various human and plant viruses. In this protocol, we present a streamlined and scalable molecular cloning strategy tailored for genome-wide and comprehensive functional characterization of viral proteins in fission yeast.

P-806 Heritable genome editing in haploid mouse embryonic stem cells

Abstract Study question Can we edit a specific gene by CRISPR-Cas9 in haploid mouse embryonic stem cells? Summary answer We successfully carried out heritable genome editing of a coat pigmentation gene in haploid mouse embryonic stem cells via electroporation. What is known already Embryonic stem cells have been widely used as a substrate to carry out genetic studies due to their availability, low cost and ease of handling. CRISPR-Cas9 has been successful in editing genes in the human model. Gene editing occurred by homology directed repair or non-homologous end joining. The utilization of a haploid genome would confirm the feasibility of non-homologous end joining repair mechanism. Study design, size, duration In the past 3 months, diploid as positive control and experimental haploid embryonic stem cells were independently cultured for genome editing experiments. Electroporation was used as a means to introduce CRISPR-Cas9 into cells. The negative control cohort consisted of embryonic stem cells electroporated without delivering any CRISPR solution. CRISPR-Cas9 was designed to knock out the Tyr gene to create an albino phenotype. Participants/materials, setting, methods Diploid embryonic stem cells were derived from C57BL/6 mice. The haploid counterpart instead was obtained from haploid androgenetic embryos using spermatozoa from Oct4-EGFP mice. CRISPR solution was prepared by combining Tyr gRNA and Cas9 protein. For each experiment, one million cells were suspended in CRISPR solution and an electroporation buffer. Then, electric pulses were applied for electroporation with 4 different parameters. Gene modification at the target site was confirmed using T7E1 cleavage assay. Main results and the role of chance A 584 base pairs region around the CRISPR target site was amplified in all the diploid and haploid mouse embryonic stem cells. After performing T7E1 cleavage assay, editing efficiency was calculated following the manufacturer protocol. Precisely, after testing out different electroporation conditions on diploid mESCs, 1350V/20ms/2 pulses together with the combination of three sgRNAs (exon 1 and exon 2) and Cas9 protein, provided the best genome editing efficiency at 36.8% with a viability of 80%. Interestingly, when delivering only one type of gRNA (exon 2) together with Cas9 protein, we saw an efficiency rising to 77.6%. We then used the same condition to edit the Tyr gene in the genome of haploid androgenetic stem cells and confirmed that also in these cells, we were able to obtain a comparable genome editing efficiency at 68.4%. Limitations, reasons for caution While these experimental observations are limited, it is encouraging that it is possible to target and edit a haploid genome with a single allele. Wider implications of the findings The utilization of a haploid cell culture model paves the way to utilize CRISPR-Cas9 for gamete genome editing. This will provide a consistent and reliable method to correct inheritable genetic conditions on gametes allowing uniform gene editing of all cell progeny. Trial registration number Not applicable

O-036 How much DNA is shared between a human egg and each of the polar bodies? Theory and genomic data from polar bodies and triploid embryos

Abstract Study question What is the proportion of the genome where the egg and the first or second polar bodies descend from the same maternal homolog? Summary answer The egg is about 30% identical to a random haploid genome from the first polar body and about 40% identical to the second polar body. What is known already After crossing over, human female meiosis generates three products: the first polar body (PBI) splits first with two sister chromatids per chromosome; the second polar body (PBII) and the egg split next, each with a single set of chromatids. When meiosis proceeds normally, the egg must be identical (i.e., same maternal homolog) to PBII at the centromeres. However, the proportion of the entire genome where the egg is identical to PBII (or to a random chromatid set from PBI), while being a fundamental property of meiosis, is not intuitively clear and has not been empirically studied. Study design, size, duration We used both theoretical and empirical approaches. We first derived formulas and performed simulations for the identity between the egg and the polar bodies, with or without modeling crossover interference. We then analyzed genotype data from seven egg/PBI/PBII trios and 43 triploid embryos. Finally, we analyzed 8,476 dizygotic twin pairs from research-consented 23andMe, Inc. customers in an attempt to find PBII twins, who would (hypothetically) share maternal genetic material in all centromeres. Participants/materials, setting, methods The egg/PBI/PBII trios came from three female donors and were genotyped at about 300k SNPs (Ottolini et al, Nat Genet, 2015). Embryos were sequenced to depth about 0.05x for routine PGT-A and identified as triploid upon retrospective analysis with LD-PGTA (Ariad et al, Genome Res, 2023). Coverage-based analysis confirmed triploidy predictions for XXY embryos. The DZ twin pairs were genotyped at about 640k SNPs and self-reported dates of birth within two days of each other. Main results and the role of chance In an infinitely long chromosome, the egg would be identical to PBII, or to a random chromatid from PBI, in only a third of its length. Modeling recombination using the human female genetic map and assuming no interference predicted that the egg would be on average 53% identical to PBII and 24% identical to a random haploid genome from PBI. We confirmed these estimates with simulations. However, in seven egg/PB1/PB2 trios, the egg was on average only 40% identical with PBII. Similarly, in 17 triploid embryos with an MII (likely-maternal) error, the two transmitted maternal chromosome sets were on average only 37% identical. Including crossover interference in the simulations reduced the identity between the egg and PBII to 42%, closer to the empirical observations. Hypothetical PBII twins would occur by two sperm from the same father fertilizing both the egg and PBII. They would share, based on the results above, an average of about 45% of their genomes. Such twins would also have identical maternal genetic material in all centromeres. In 8,476 genetically dizygotic twin pairs, only 67 shared at least one haplotype in all centromeres, not significantly more than expected by chance for dizygotic twins. Limitations, reasons for caution The empirical results are based on a small number of egg/PBI/PBII trios (n = 7) from only three donors. The number of triploid embryos was larger, but they were sequenced to very low depth, and the results for MI-error embryos showed much less sharing between the two maternal chromosomes than expected. Wider implications of the findings We show the fundamental and perhaps counter-intuitive result that the egg is only 30-40% identical to the polar bodies. This provides a reference against which deviations from normal crossover patterns could be evaluated in triploid and other aneuploid embryos. Polar body twins, if they occur, must be extremely rare. Trial registration number Not applicable

Long-Read-Based Hybrid Genome Assembly and Annotation of Snow Algal Strain CCCryo 101-99 (cf. Sphaerocystis sp., Chlamydomonadales).

Polar regions harbor a diversity of cold-adapted (cryophilic) algae, which can be categorized into psychrophilic (obligate cryophilic) and cryotrophic (nonobligate cryophilic) snow algae. Both can accumulate significant biomasses on glacier and snow habitats and play major roles in global climate dynamics. Despite their significance, genomic studies on these organisms remain scarce, hindering our understanding of their evolutionary history and adaptive mechanisms in the face of climate change. Here, we present the draft genome assembly and annotation of the psychrophilic snow algal strain CCCryo 101-99 (cf. Sphaerocystis sp.). The draft haploid genome assembly is 122.5 Mb in length and is represented by 664 contigs with an N50 of 0.86 Mb, a Benchmarking Universal Single-Copy Orthologs (BUSCO) completeness of 92.9% (n = 1,519), a maximum contig length of 5.3 Mb, and a guanine-cystosine (GC) content of 53.1%. In total, 28.98% of the genome (35.5 Mb) contains repetitive elements. We identified 417 noncoding RNAs and annotated the chloroplast genome. The predicted proteome comprises 14,805 genes with a BUSCO completeness of 97.8%. Our preliminary analyses reveal a genome with a higher repeat content compared with mesophilic chlorophyte relatives, alongside enrichment in gene families associated with photosynthesis and flagella functions. Our current data will facilitate future comparative studies, improving our understanding of the likely response of polar algae to a warming climate as well as their evolutionary trajectories in permanently cold environments.

Exploring the maternal inheritance transmitted by the oocyte to its progeny.

Fertility is declining worldwide and many couples are turning towards assisted reproductive technologies (ART) to conceive babies. Organisms that propagate via sexual reproduction often come from the fusion between two gametes, an oocyte and a sperm, whose qualities seem to be decreasing in the human species. Interestingly, while the sperm mostly transmits its haploid genome, the oocyte transmits not only its haploid set of chromosomes but also its huge cytoplasm to its progeny. This is what can be defined as the maternal inheritance composed of chromosomes, organelles, lipids, metabolites, proteins and RNAs. To decipher the decline in oocyte quality, it is essential to explore the nature of the maternal inheritance, and therefore study the last stages of murine oogenesis, namely the end of oocyte growth followed by the two meiotic divisions. These divisions are extremely asymmetric in terms of the size of the daughter cells, allowing to preserve the maternal inheritance accumulated during oocyte growth within these huge cells to support early embryo development. Studies performed in Marie-Hélène Verlhac's lab have allowed to discover the unprecedented impact of original acto-myosin based mechanisms in the constitution as well as the preservation of this maternal inheritance and the consequences when these processes go awry.

De Novo Assembly and Annotation of the Siganus fuscescens (Houttuyn, 1782) Genome: Marking a Pioneering Advance for the Siganidae Family.

This study presents the first draft genome of Siganus fuscescens, and thereby establishes the first whole-genome sequence for a species in the Siganidae family. Leveraging both long and short read sequencing technologies, i.e., Oxford Nanopore and Illumina sequencing, we successfully assembled a mitogenome spanning 16.494 Kb and a first haploid genome encompassing 498Mb. The assembled genome accounted for a 99.6% of the estimated genome size and was organized into 164 contigs with an N50 of 7.2Mb. This genome assembly showed a GC content of 42.9% and a high Benchmarking Universal Single-Copy Orthologue (BUSCO) completeness score of 99.5% using actinopterygii_odb10 lineage, thereby meeting stringent quality standards. In addition to its structural aspects, our study also examined the functional genomics of this species, including the intricate capacity to biosynthesize long-chain polyunsaturated fatty acids (LC-PUFAs) and secrete venom. Notably, our analyses revealed various repeats elements, which collectively constituted 17.43% of the genome. Moreover, annotation of 28,351 genes uncovered both shared genetic signatures and those that are unique to S. fuscescens. Our assembled genome also displayed a moderate prevalence of gene duplication compared to other fish species, which suggests that this species has a distinctive evolutionary trajectory and potentially unique functional constraints. Taken altogether, this genomic resource establishes a robust foundation for future research on the biology, evolution, and the aquaculture potential of S. fuscescens.

The reference genome of an endangered Asteraceae, Deinandra increscens subsp. villosa, endemic to the Central Coast of California.

We present a reference genome for the federally endangered Gaviota tarplant, Deinandra increscens subsp. villosa (Madiinae, Asteraceae), an annual herb endemic to the Central California coast. Generating PacBio HiFi, Oxford Nanopore Technologies, and Dovetail Omni-C data, we assembled a haploid consensus genome of 1.67 Gb as 28.7 K scaffolds with a scaffold N50 of 74.9 Mb. We annotated repeat content in 74.8% of the genome. Long terminal repeats (LTRs) covered 44.0% of the genome with Copia families predominant at 22.9% followed by Gypsy at 14.2%. Both Gypsy and Copia elements were common in ancestral peaks of LTRs, and the most abundant element was a Gypsy element containing nested Copia/Angela sequence similarity, reflecting a complex evolutionary history of repeat activity. Gene annotation produced 33,257 genes and 68,942 transcripts, of which 99% were functionally annotated. BUSCO scores for the annotated proteins were 96.0% complete of which 77.6% was single copy and 18.4% duplicates. Whole genome duplication synonymous mutation rates of Gaviota tarplant and sunflower (Helianthus annuus) shared peaks that correspond to the last Asteraceae polyploidization event and subsequent divergence from a common ancestor at ∼27 MYA. Regions of high-density tandem genes were identified, pointing to potentially important loci of environmental adaptation in this species.