In phylogenetic analysis, long-branch attraction (LBA) occurs when two distantly related species with longer branches are mistakenly grouped as the most closely related species. Previous research addressing this issue has focused on phylogenetic trees with four operational taxonomic units and three topologies, using two models: the Felsenstein model tree, which has two long branches that are not closely related, and the Farris tree, which has two long branches that are most closely related. For the Felsenstein model, the maximum parsimony method is more prone to estimating incorrect tree shapes compared to the maximum likelihood (ML) method, whereas in the Farris model, the opposite tendency is observed. However, the underlying reason for these differences remains unclear. Therefore, we inferred phylogenetic trees using sequence data from molecular evolution simulations of model phylogenetic trees with different long-branch lengths and measured the tree shapes and branch lengths of the obtained phylogenetic trees. Our findings revealed that tree inference bias caused by the presence of long branches (defined as 'long-branch bias') increases with the accumulation of mutations, and influences all model trees or phylogenetic inference methods. In other words, in Felsenstein tree models, methods that are highly sensitive to long-branch bias tend to cause LBA, and in Farris tree models, the methods tend to infer apparently correct phylogenetic trees because of this influence. Thus, methods sensitive to long-branch bias always infer the same tree shape. Additionally, long-branch bias causes similar misestimations of branch lengths in both Felsenstein and Farris trees inferred by neighbor-joining or ML. This insight into long-branch bias will lead to a more reliable interpretation of phylogenetic trees, such as the shift of branching points, improving the accuracy of future research in molecular evolution.

The sequencing of PCR fragments amplified from specific regions of genomes is a fundamental technique in molecular genetics. Sanger sequencing is commonly used for this analysis; however, amplicon sequencing utilizing next-generation sequencing has become widespread. In addition, long-read amplicon sequencing, using Nanopore or PacBio sequencers to analyze long PCR fragments, has emerged, although it is often more expensive than Sanger sequencing. Recently, low-cost commercial services for full-length plasmid DNA sequencing using Nanopore sequencers have been launched in several countries, including Japan. This study explored the potential of these services to sequence long PCR fragments without the need for cloning into plasmid DNA, as cloning long PCR fragments or blunt-end PCR fragments into plasmids is often challenging. PCR fragments of 4-11 kb, amplified from the DFR-B gene involved in the biosynthesis of anthocyanin, with or without Tpn1 transposons in Japanese morning glory (Ipomoea nil), were circularized using T4 DNA ligase and analyzed as templates. Although some inaccuracies in the length of homopolymer stretches were observed, the remaining sequences were obtained without significant errors. This method could potentially reduce the labor and costs associated with cloning, primer synthesis and sequence assembly, thus making it a viable option for the analysis of long PCR fragment sequences. Moreover, this study reconfirmed that Tpn1 transposons are major mutagens in I. nil and demonstrated their transposition in the Violet line, a long-used standard in plant physiology.

Testicular differentiation of undifferentiated gonads is triggered by the SRY/Sry (sex-determining region of chromosome Y) gene on the Y chromosome in most mammals. SRY and NR5A1 (nuclear receptor subfamily 5, group A, member 1) proteins regulate transcription of the autosomal SOX9/Sox9 (SRY-box9) gene in XY embryonic gonads, inducing testicular differentiation. One exception, the Amami spiny rat (Tokudaia osimensis), lacks the Y chromosome and Sry. We previously reported that this species has a male-specific duplication upstream of Sox9, and an enhancer (tosEnh14) in the duplication regulates Sox9 transcription without Sry. However, tosEnh14 is not activated by NR5A1 alone, suggesting that another transcription factor(s) which binds to tosEnh14 is necessary. Because this species is endangered and heavily protected, it presents many challenges for genetic studies. Therefore, we explored novel transcription factors that regulate Sox9 via tosEnh14 using mouse samples. To detect proteins that bind to tosEnh14 DNA, Southwestern blotting analysis was performed using mouse embryonic gonad extracts. Bands of a similar molecular weight but prominent in males and faint in females were subjected to mass spectrometry analysis. Peptides derived from 174 genes were identified, and eight genes associated with gene ontology terms such as "DNA binding" and "regulation of transcription by RNA polymerase II" were selected. For further screening, the expression level of each gene was examined using single-cell RNA-sequencing data for mouse progenitor cells, which differentiate into Sertoli cells in mouse embryonic testes and granulosa cells in embryonic ovaries. Finally, five genes (Elf2, Etv6, Fiz1, Gtf2f1 and Trim27) encoding transcription factors, whose expression was confirmed in seminiferous tubules of E13.5 XY embryos by whole-mount in situ hybridization, were selected as candidates. Binding sites for ELF2 and ETV6 are present in the tosEnh14 DNA sequence. Our study contributes to understanding the molecular mechanisms underlying sex determination in mammals.

DNA methylation is faithfully inherited during cell division, playing a crucial role in maintaining cellular identity. The process of DNA methylation maintenance relies on the DNA methyltransferase DNMT1 and the ubiquitin E3 ligase UHRF1. UHRF1 facilitates the ubiquitination of both the replication factor PAF15 and histone H3, with each ubiquitin signal regulating replication-coupled and -uncoupled DNA methylation maintenance, respectively. Over the past decades, advances in structural biology have significantly deepened our understanding of the molecular mechanisms governing DNA methylation maintenance. In particular, the emergence of cryo-electron microscopy-often referred to as the "resolution revolution"-has transformed many areas of biology, including epigenetics and chromatin biology. This review focuses on the structural mechanisms of DNA methylation maintenance, as revealed by the three-dimensional structures of key biomolecular complexes, and discusses the potential development of inhibitors targeting DNA methylation maintenance factors based on structural insights.

Primula tibetica is an insect-pollinated, herbaceous, perennial plant belonging to the section Aleuritia (Primulaceae). The species exhibits the typical characteristics of heterostyly, with predominantly outcrossing populations comprising long-styled and short-styled floral morphs. Furthermore, significant variation occurs in floral morphology, categorised as homostyly, a phenomenon commonly associated with elevated selfing rates. Utilising next-generation sequencing, 25 microsatellite markers for P. tibetica were developed, with the objective of facilitating future investigations into the population genetics and mating patterns of the species. These markers were characterised by measuring polymorphism and genetic diversity in a sample of 36 individuals from three natural populations. The markers displayed relatively high polymorphism, with the number of observed alleles per locus ranging from two to 15 (mean = 7.26). The observed and expected heterozygosities ranged from 0.056 to 0.917 and 0.105 to 0.825, respectively. Furthermore, nineteen of these loci were also successfully amplified in P. pulchella. These microsatellite markers should serve as effective tools for investigating patterns of population genetic diversity and elucidating the evolutionary relationship between distyly and homostyly in P. tibetica.

β-sitosterol is a natural plant steroidal compound with anti-cancer properties against various tumors. This work explored the inhibitory effect of β-sitosterol on the progression of lung adenocarcinoma (LUAD) and further analyzed its targets. We applied network pharmacology to obtain the components and targets of Ganoderma spore powder. The biological functions of β-sitosterol and CHRM2 were studied using the homograft mouse model and a series of in vitro experiments involving quantitative reverse transcription polymerase chain reaction, western blot, CCK-8, flow cytometry, immunohistochemistry and immunofluorescence. The regulatory influence of β-sitosterol on the glycolysis pathway was validated by measuring glucose consumption and lactate production, as well as the extracellular acidification rate and oxygen consumption rate. We found that CHRM2 binds directly to β-sitosterol. In vitro, CHRM2 overexpression repressed the apoptosis rate and expression of apoptosis-related proteins in LUAD cells, and promoted glycolysis, while the addition of lonidamine attenuated the apoptosis-inhibiting effect conferred by CHRM2 overexpression. Furthermore, β-sitosterol hindered glycolysis as well as the growth of tumors in vitro and in vivo. CHRM2 overexpression reversed the effect of β-sitosterol on the biological behavior of LUAD cells. Our results emphasize that CHRM2 is a direct target of β-sitosterol in LUAD cells. β-sitosterol can repress the glycolysis pathway, exerting an anti-tumor effect. These findings provide new support for the use of β-sitosterol as a therapeutic agent for LUAD.

The mammalian sex-determining gene SRY is highly conserved across species, with only a few exceptions. The Japanese rodent genus Tokudaia is known for its unique sex chromosome evolution. The Okinawa spiny rat T. muenninki (TMU) acquired neo-sex chromosomes with multiple Sry copies by sex chromosome-autosome fusions. All SRY copies in TMU have a substitution from alanine to serine at position 21 in the high-mobility group (HMG) box, a critical DNA-binding domain, suggesting that they are nonfunctional. However, the sex determination system in TMU remains unclear, in part because the species is endangered and it is therefore extremely difficult to obtain experimental samples. In this study, we performed in silico and in vitro analyses to investigate the molecular properties and function of SRY using recently obtained whole-genome sequence and RNA-seq data. A comparison of SRY sequences from 225 species showed that TMU is the only species with a substitution at the 21st position. This result highlights the rarity and specificity of this substitution. Structural predictions, DNA docking simulations, electrophoretic mobility shift assays and fluorescence anisotropy showed that although the affinity was slightly lower than that of the mouse homolog, DNA-binding ability was retained. However, Sry expression was not detected in the testis, liver or brain in adult TMU. The complete absence of Sry expression in the adult tissues, despite an intact sequence, strongly indicates a loss of regulatory function. These findings provide insight into the unique evolution of the Sry gene in this species.

YchF is a universally conserved unconventional G protein. It is known to be involved in the translation of leaderless mRNA. However, leaderless mRNA is rare in Escherichia coli under normal culture conditions, so we analyzed E. coli YchF to clarify its function in vivo. First, bioinformatics analysis was performed, and then the growth and survival of ychF mutants were investigated. The results suggest that the functional domains and important amino acid residues of YchF are conserved. We next found that the ychF mutants exhibited delayed re-growth in late stationary phase in the presence of oxidative stress. Moreover, the growth inhibition by catalase overexpression was suggested to be caused by oxidase activity. We found that the E. coli ychF mutants exhibited reduced growth in early stationary phase that was associated with a decreased level of ribosomal 70S subunit. In the ychF mutants, we also found that overproduction of the ribosomal protein S18 inhibited growth, which was further suppressed by overproduction of S11. YchF of E. coli is involved in the regulation of ribosomal 70S levels possibly through interaction with ribosomal proteins S18 and S11 as well as IF-3, suggesting that YchF is important for growth and survival in the early and late stationary phase of growth.

Sex-specific DNA markers are effective tools for sex identification and sex-controlled breeding of dioecious organisms. The seeds of the dioecious Herpetospermum pedunculosum are utilized in traditional Chinese medicine, and the development of sex-linked markers for seedlings is crucial for enhancing the number of female plants. In this study, we screened sex-specific markers based on whole-genome resequencing of 20 male and 24 female H. pedunculosum individuals, and validated a male-specific DNA fragment of 505 bp among 80 individuals from four populations using simple PCR. The findings provide a reliable male-specific marker for the sex identification of H. pedunculosum seedlings.

Cytokinin plays a major role in the regulation of plant development. It is perceived by receptors with histidine kinase activity to regulate the expression of various transcription factors. In a previous study, we reported a semi-dominant mutant, named adaxial-abaxial bipolar leaf1 (abl1)-d, which exhibited a characteristic feature in the fourth leaf of rice, and that the ABL1 gene encodes a cytokinin receptor with histidine kinase activity. Our further analysis suggested that the abl1-d mutation is associated with an active form of histidine kinase and altered cytokinin signaling. However, it remained unclear whether the abl1-d mutation indeed triggers aberrant cytokinin signaling in rice plants, and how the abl1-d mutation affects developmental processes throughout the life cycle of rice. In the present study, we found that homozygous abl1-1d calli have the capacity to regenerate shoots in the absence of cytokinin, suggesting that the abl1-1d homozygous mutation is associated with constitutive cytokinin signaling in rice. We next examined morphological characteristics of both homozygous and heterozygous abl1-1d plants from the post-germination vegetative phase through to reproduction. The results showed that homozygous abl1-1d plants had a reduced number of panicles and were completely sterile, and that leaf size and the midrib structure were altered. Furthermore, the adaxial-abaxial bipolar leaf, a phenotype that is characteristic of the abl1-1d mutant, has previously been observed to resemble two normal leaves fused together at their abaxial sides. Leaves with this particular phenotype exhibited enhanced photosynthetic efficiency under certain environmental conditions. Thus, the abl1-1d mutation, which results in a putative active form of receptor histidine kinase, affects various developmental traits throughout the rice life cycle, probably due to altered cytokinin signaling.