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Chromosome painting is a useful technique for distinguishing specific chromosomes (fragments), elucidating the genetic relationships of different genomes or chromosomes, and identifying chromosomal rearrangements. The development of chromosome- or genome-specific probes is fundamental for chromosome painting. The possibility for developing such probes specifically painting homoeologous chromosomes in allopolyploid species has been questioned since that chromosomes belonging to the same homoeologous group share highly conserved sequences. In the present study, we attempted to construct a wheat chromosome 4D-specific oligo probe library by selecting 4D-specific sequences in reference genome of common wheat cv. Chinese Spring (CS, 2n = 6x = 42, AABBDD). The synthesized library contains 27,392 oligos. Oligo painting using the probe library confirmed its specificity, shown by that only chromosome 4D could be painted in three wheat genotypes and CS nulli-tetrasomic line N4AT4D. Oligo painting was successfully used to define the 4D breakpoints in CS deletion lines involving 4D and two wheat-Haynaldia villosa 4D–4V translocation lines. Thirteen wheat relatives and a Triticum durum-H. villosa amphiploid were used for oligo painting. Except the 4D in two Aegilops tauschii accessions, the 4M in Ae. comosa and 4U in Ae. umbellulata could be painted. In tetraploid Ae. ventricosa, both 4D and 4M could be painted; however, the signal intensity of 4M was less compared with 4D. No painted chromosome was observed for the other alien species. This indicated that the relationship among D/M/U was closer than that among D/A/B as well as D with genomes H/R/Ss/Sc/Y/P/N/J. Our successful development of 4D-specific oligo probe library may serve as a model for developing oligo probes specific for other homoeologous chromosomes.

Agrobacterium-mediated genetic transformation is well established in the model grass Brachypodium distachyon. However, most protocols employ immature embryos because of their better regenerative capacity. A major problem associated with the immature embryo system is that they are available only during a limited time window of growing plants. In this study, we have developed an optimized Agrobacterium-mediated genetic transformation protocol that utilizes mature embryos. We have adopted seed shearing and photoautotrophic rooting (PR) in callus induction and root regeneration, respectively, with evident significant improvement in these aspects. We have also revealed that the newly developed chemical inducer Fipexide (FPX) had the ability to induce callus, shoots, and roots. By comparison, we have demonstrated that FPX shows higher efficiency in shoot generation than other frequently used chemicals in our mature embryo-based system. In addition, we demonstrated that the age of embryogenetic callus severely affects the transformation efficiency (TE), with the seven-week-old embryogenetic callus having the highest TE reaching 52.6%, which is comparable with that in immature embryo transformation. The new methodologies reported here will advance the development and utilization of Brachypodium as a new model system for grass genomics.

The genus Populus is composed of dioecious woody plants and adult females produce large numbers of seed hairs that can affect public health and pose a potential fire risk. However, it is difficult to distinguish between males and females based on their morphology at the seedling stage. Therefore, developing a technology that identifies the gender of poplar seedlings is crucial for controlling seed hairs. In this study, we developed an approach for the early gender identification of Tacamahaca and Aigeiros species based on the male-specific sequence in Populus simonii. The gender of Tacamahaca and Aigeiros species can be accurately identified by PCR. The sequencing results showed that the male-specific sequence was conserved in P. simonii and its F1 progenies. Interestingly, there were three nucleobase differences between Tacamahaca and Aigeiros species. Sequence alignment showed that the male-specific sequence had not been assembled on the pseudochromosome. Subsequently, fluorescence in situ hybridization (FISH) was used to locate this specific sequence at the short arm end of chromosome 19 in male P. simonii. This study provides an efficient and convenient method for early gender determination of Tacamahaca and Aigeiros species and lays the groundwork for exploring key sex-determination genes.

An efficient in vitro mutagenesis protocol for Lilium longiflorum Thunb. cv. White fox has been established. The effect of 6-BA and NAA on adventitious bud formation from the bulblet-scale thin cell layers was tested. Results showed that the optimal medium for adventitious bud induction is MS basal medium supplemented with 2.0 mg/l 6-BA and 0.1 mg/l NAA. The differentiation frequency and the average number of adventitious buds reached 95.55% and 3.00, respectively. Various doses (0.0, 0.5, 1.0, 1.5, 2.0, and 2.5 Gy) of gamma rays were applied to investigate the effect of radiation on adventitious bud formation from bulblet-scale thin cell layers. The forming capacity of the adventitious buds significantly decreased with the increase of radiation dose. The results suggested that the optimal irradiation dose is 1.0 Gy. Dose of 1.0 Gy treatment resulted in 55.33% survival of irradiated bulblet-scale thin cell layers and 39.27% mutagenesis rate. The genetic variations among the morphological mutants were evaluated by DNA fingerprinting using ISSR molecular marker. The genetic variation frequency reached 36.06% using seven ISSR primers. Out of the 50 mutant lines transferred to the greenhouse, 9 were observed to have significantly different morphological characters than those of the controls.

Brachypodium distachyon, a new monocotyledonous model plant, has received wide attention in biological research due to its small genome and numerous genetic resources. Codon usage bias is an important feature of genes and genomes, and it can be used in transgenic and evolutionary studies. In this study, the nucleotide compositions and patterns of codon usage bias were calculated using Codon W. Additionally, an ENC plot, Parity rule 2 and correspondence analyses were used to explore the major factors influencing codon usage bias patterns. The numbers of hydrogen bonds and skews were used to analyze the GC trend in the 5′-ends of the coding sequences. The results showed that minor differences in the codon usage bias patterns were revealed by the ENC plot, Parity rule 2 and correspondence analyses. The analyses of the CG-skew and the number of hydrogen bonds showed a declining trend in the number of cytosines at the 5′-ends of the CDSs (from the 5′-ends to the 3′-ends), indicating that GC may play a major role in codon usage bias. In addition, our results laid a foundation for the study of codon usage bias patterns in Brachypodium genus and suggested that the GC plays a major role in determining these patterns.

Key message Fluorescence in situ hybridization with frozen sections of root tips showed difference of chromosome territories distribution between autosome and sex-chromosome homologous pairs in Populus trichocarpa . The spatial organization of chromatin within the interphase nucleus and the interactions between chromosome territories (CTs) are essential for various biologic processes. Three-dimensional fluorescence in situ hybridization (3D-FISH) is a powerful tool for analyzing CTs, but its application in plants is limited. In this study, we established a 3D-FISH technique using frozen sections of Populus trichocarpa root tips, which was an improvement over the use of paraffin sections and enabled us to acquire good FISH signals. Using chromosome-specific oligo probes, we were able to analyze CTs in interphase nuclei in three dimensions. The distribution of chromosome pairs 17 and 19 in the 3D-preserved nuclei of P. trichocarpa root tip cells were analyzed and showed that the autosome pair 17 associated more often than sex chromosome 19. This research lays a foundation for further study of the spatial position of chromosomes in the nucleus and the relationship between gene expression and spatial localization of chromosomes in poplar.

The camphor tree (Cinnamomum camphora (L.) Presl.) is the representative species of subtropical evergreen broadleaved forests in eastern Asia and an important raw material for essential oil production worldwide. Although MYBs have been comprehensively characterized and their functions have been partially resolved in many plants, it has not been explored in C. camphora. In this study, 121 CcMYBs were identified on 12 chromosomes in the whole genome of C. camphora and found that CcMYBs were mainly expanded by segmental duplication. They were divided into 28 subgroups based on phylogenetic analysis and gene structural characteristics. In the promoter regions, numerous cis-acting elements were related to biological processes. Analysis of RNA sequencing data from seven tissues showed that CcMYBs exhibited different expression profiles, suggesting that they have various roles in camphor tree development. In addition, combined with the correlation analysis of structural genes in the flavonoid synthesis pathway, we identified CcMYBs from three subgroups that might be related to the flavonoid biosynthesis pathway. This study systematically analyzed CcMYBs in C. camphora, which will set the stage for subsequent research on the functions of CcMYBs during their lifetime and provide valuable insights for the genetic improvement of camphor trees.

Poplar was one of the first woody species whose individual chromosomes could be identified using chromosome specific painting probes. Nevertheless, high-resolution karyotype construction remains a challenge. Here, we developed a karyotype based on the meiotic pachytene chromosome of Populus simonii which is a Chinese native species with many excellent traits. This karyotype was anchored by oligonucleotide (oligo)-based chromosome specific painting probes, a centromere-specific repeat (Ps34), ribosomal DNA, and telomeric DNA. We updated the known karyotype formula for P. simonii to 2n = 2x = 38 = 26m + 8st + 4t and the karyotype was 2C. The fluorescence in situ hybridization (FISH) results revealed some errors in the current P. simonii genome assembly. The 45S rDNA loci were located at the end of the short arm of chromosomes 8 and 14 by FISH. However, they were assembled on pseudochromosomes 8 and 15. In addition, the Ps34 loci were distributed in every centromere of the P. simonii chromosome in the FISH results, but they were only found to be present in pseudochromosomes 1, 3, 6, 10, 16, 17, 18, and 19. Our results reveal that pachytene chromosomes oligo-FISH is a powerful tool for constructing high-resolution karyotypes and improving the quality of genome assembly.

The ‘Menglina Leddy’ lily cultivar was selected from the Lilium longiflorum Thunb. ‘White Fox’ γ-rays irradiation line. It produces much less pollen than ‘White Fox’ but has similar morphology traits. In order to reveal the effects of gamma irradiations on the chromosomes, mitosis, and meiosis in ‘Menglina Leddy’ cells were investigated by fluorescence in situ hybridization using rDNA and telomeric repeat probes. Although both ‘Menglina Leddy’ and ‘White Fox’ had 24 chromosomes, a considerable amount of chromosomal breaking and rejoining were detected in the former. A super long and two super small chromosomes appeared in all the ‘Menglina Leddy’ cells. Meiotic abnormalities occurred at each separation stage. Chromosomes pairing configuration showed that complex recombination had happened in ‘Menglina Leddy’. The super long chromosome was a Robertsonian translocation product composed of two non-homologous long arms. The chromosome deletions and recombinations did not affect the main ornamental traits, but allowed it to acquire the characteristic of less pollen.

Dioecious species accounted for 6% of all plant species, including a number of crops and economically important species, such as poplar. However, sex determination and sex chromosome evolution have been studied only in few dioecious species. In poplar, the sex-determining locus was mapped to chromosome 19. Interestingly, this locus was mapped to either a peritelomeric or a centromeric region among different poplar species. We developed an oligonucleotide (oligo)-based chromosome painting probe based on the sequence of chromosome 19 from Populus trichocarpa. We performed chromosome painting in P. tomentosa and P. deltoides. Surprisingly, the distal end on the short arm of chromosome 19, which corresponds to the location of the sex-determining locus reported in several species, was not painted in both species. Thus, the DNA sequences associated with this region have not been anchored to the current chromosome 19 pseudomolecule, which was confirmed by painting of somatic metaphase chromosome 19 of P. trichocarpa. Interestingly, the unpainted distal ends of the two chromosome 19 did not pair at the pachytene stage in 22–24% of the meiotic cells in the two species, suggest that these regions from the sex chromosomes have structurally diverged from each other, resulting in the reduced pairing frequency. These results shed light on divergence of a pair of young sex chromosomes in poplar.