Karyotype Differentiation in Cultivated Chickpea Revealed by Oligopainting Fluorescence in situ Hybridization

A multidisciplinary and integrative review of the structural genome and epigenome of Capsicum L. species

MAIN CONCLUSION

We revised and integrated the genomic and epigenomic data into a comparative Capsicum ideogram, evidencing the advances and future perspectives. Capsicum L. (Solanaceae) genome has been characterized concerning karyotype, nuclear and chromosomal genome size, genome sequencing and physical mapping. In addition, the epigenome has been investigated, showing chromosomal distribution of epimarks in histone amino acids. Genetic and epigenetic discoveries have given light to understanding the structure and organization of the Capsicum "omics". In addition, interspecific and intraspecific similarities and diversities have been identified, characterized and compared in taxonomic and evolutive scenarios. The journey through Capsicum studies allows us to know the 2n = 2x = 24 and 2n = 2x = 26 chromosome numbers, as well as the relatively homomorphic karyotype, and the 1C chromosomal DNA content. In addition, Capsicum "omics" diversity has mainly been evidenced from the nuclear 1C value, as well as from repeatome composition and mapping. Like this, Capsicum provides several opportunities for "omics", ecological, agronomic and conservation approaches, as well as subjects that can be used at different levels of education. In this context, we revisit and integrate Capsicum data about the genome size, karyotype, sequencing and cytogenomics, pointing out the progress and impact of this knowledge in taxonomic, evolutive and agronomic contexts. We also noticed gaps, which can be a focus of further studies. From this multidisciplinary and integrative review, we intend to show the beauty and intrigue of the Capsicum genome and epigenome, as well as the outcomes of these similarities and differences.

A cost-effective oligo-based barcode system for chromosome identification in longan and lychee

Oligonucleotide (Oligo)-based fluorescence in situ hybridization (FISH) represents a highly effective methodology for identifying plant chromosomes. Longan is a commercially significant fruit species, yet lacking basic chromosomal markers has hindered its cytogenetic research. In this study, we developed a cost-effective oligo-based system for distinguishing chromosomes of longan (Dimocarpus longan Lour., 2n = 2x = 30). For this system, each synthesized oligo contained two chromosome-specific sequences that spanned a distance of over 200 kb, and a PCR-based flexible amplification method coupled with nested primers was used for probe labeling. The use of these oligo-based barcodes enabled the marking of 36 chromosomal regions, which allowed for the unambiguous distinction of all 15 chromosomes in both longan and lychee (Litchi chinensis Sonn., 2n = 2x = 30) species. Based on the identification of individual chromosomes, we constructed karyotypes and detected genome assembly errors involving the 35S ribosomal RNA gene (35S rDNA) in longan and lychee. Developing oligo-based barcodes offers considerable promise for advancing cytogenetic research in longan, lychee, and their related species. Furthermore, this cost-effective synthesis system can be referred to the development of new oligo libraries among other species.

Oligo-barcode illuminates holocentric karyotype evolution in Rhynchospora (Cyperaceae)

Holocentric karyotypes are assumed to rapidly evolve through chromosome fusions and fissions due to the diffuse nature of their centromeres. Here, we took advantage of the recent availability of a chromosome-scale reference genome for Rhynchospora breviuscula, a model species of this holocentric genus, and developed the first set of oligo-based barcode probes for a holocentric plant. These probes were applied to 13 additional species of the genus, aiming to investigate the evolutionary dynamics driving the karyotype evolution in Rhynchospora. The two sets of probes were composed of 27,392 (green) and 23,968 (magenta) oligonucleotides (45-nt long), and generated 15 distinct FISH signals as a unique barcode pattern for the identification of all five chromosome pairs of the R. breviuscula karyotype. Oligo-FISH comparative analyzes revealed different types of rearrangements, such as fusions, fissions, putative inversions and translocations, as well as genomic duplications among the analyzed species. Two rounds of whole genome duplication (WGD) were demonstrated in R. pubera, but both analyzed accessions differed in the complex chain of events that gave rise to its large, structurally diploidized karyotypes with 2n = 10 or 12. Considering the phylogenetic relationships and divergence time of the species, the specificity and synteny of the probes were maintained up to species with a divergence time of ~25 My. However, karyotype divergence in more distant species hindered chromosome mapping and the inference of specific events. This barcoding system is a powerful tool to study chromosomal variations and genomic evolution in holocentric chromosomes of Rhynchospora species.

Tracing the Evolution of the Angiosperm Genome from the Cytogenetic Point of View

Cytogenetics constitutes a branch of genetics that is focused on the cellular components, especially chromosomes, in relation to heredity and genome structure, function and evolution. The use of modern cytogenetic approaches and the latest microscopes with image acquisition and processing systems enables the simultaneous two- or three-dimensional, multicolour visualisation of both single-copy and highly-repetitive sequences in the plant genome. The data that is gathered using the cytogenetic methods in the phylogenetic background enable tracing the evolution of the plant genome that involve changes in: (i) genome sizes; (ii) chromosome numbers and morphology; (iii) the content of repetitive sequences and (iv) ploidy level. Modern cytogenetic approaches such as FISH using chromosome- and genome-specific probes have been widely used in studies of the evolution of diploids and the consequences of polyploidy. Nowadays, modern cytogenetics complements analyses in other fields of cell biology and constitutes the linkage between genetics, molecular biology and genomics.