Acute toxicity of Jatropha curcas oil on plant cell cycle

Today, a great interest in Jatropha-based products exists worldwide, mainly for the production of biofuel. However, the oil obtained from this plant is known to be toxic due to contained curcins and phorbol esters. Bioassays, including plant cytogenetic assays based on cell cycle observation, are useful for determining the toxicity of J. curcas oil. Hence, the aim of this study was to describe the mechanism of action of J. curcas oil by cell cycle analysis using Lactuca sativa as plant testing model. A decrease in root growth was observed, closely related to the reduction in mitotic index, along with an increase in condensed nuclei. J. curcas chemicals act both as aneugenic agents, leading to the formation of lagged, sticky chromosomes and c-metaphase cells, as well as clastogenic agents, inducing the formation of chromosome bridges and fragments. The cytotoxicity and genotoxicity of phorbol esters and other chemical components of J. curcas oil was determined and discussed

C-value reassessment of plant standards: an image cytometry approach

Image cytometry (ICM) has been used to measure DNA 2C-values by evaluating the optical density of Feulgen-stained nuclei. This optical measurement is carried out using three basic tools: microscopy, digital video camera, and image analysis software. Because ICM has been applied to plants, some authors have remarked that studies should be performed before this technique can be accepted as an accurate method for determination of plant genome size. Based on this, the 2C-value of eight plants, which are widely used as standards in DNA quantifications, was reassessed in a cascade-like manner, from A. thaliana through R. sativus, S. lycopersicum, Glycine max, Z. mays, P. sativum, V. faba, to A. cepa. The mean 2C-values of all plants were statistically compared to the values reported by other authors using flow cytometry and/or ICM. These analyses demonstrated that ICM is an accurate and reliable method for 2C-value measurement, representing an attractive alternative to flow cytometry. Statistical comparison of the results also indicated Glycine max ‘Polanka’ as the most adequate primary standard. However, distinct authors have been advised that 2C DNA content of the reference standard should be close to that of the sample. As three further approaches also revisited the 2C-value of these eight plants, we have thus proposed a mean 2C-value for each eight species

Karyotype revised of Pisum sativum using chromosomal DNA amount

Pisum sativum was one of the first plants for which the mitotic karyotype was recognized and the karyogram assembled. These achievements were required owing to the physical mapping of P. sativum, providing data for evolutionary approaches and breeding programs. In spite of significant advances, precise morphometric characterization of chromosomes and karyogram assembly of P. sativum have become a topical problem. The present study proposes an unambiguous classification for the chromosomes of P. sativum, based on classical cytogenetic rules and chromosomal DNA amount. Cytogenetic procedure yielded mitotic cells showing morphologically preserved and stoichiometrically stained chromosomes. Twelve mitotic cells were selected, and the mean values for total, short- and long-arm lengths and DNA amount were measured for each chromosome. Chromosomal DNA amount fully correlated with total chromosome length, whose value proportionally decreases with the amount of DNA. Considering these data, all seven chromosomes could be unambiguously identified, yielding a new cytogenetic classification for P. sativum chromosomes. Moreover, the chromosome pairs were ordered according to the classical cytogenetic rule for assembly of karyograms. Since P. sativum is considered a model plant, it was possible to correlate the newly outlined karyotype with other cytogenetic data and linkage groups

Revisiting the DNA C-values of the genome size-standards used in plant flow cytometry to choose the “best primary standards”

Flow cytometry (FCM) techniques have enabled characterization of the genome size for various plant species. In order to measure the nuclear genome size of a species, reference standards with well-established DNA content are necessary. However, different 2C-values have been described for the same species used as reference standard. This fact has brought about inaccurate genome measurements, making relevant the establishment of optimal DNA reference standards for plant cytometric analyses. Our work revisited the genome size of Arabidopsis thaliana and other seven plant standards, which were denominated “Doležel’s standard set” and have been widely used in plant DNA measurements. These eight plant standards were reassessed for a comparative measurement of their DNA content values, using each plant species as primary standard in a cascade-like manner, from A. thaliana to Allium cepa. The genome size values obtained here were compared to those reported in the literature by statistical analyses. As a result, Raphanus sativus and Drosophila melanogaster were considered the most inadequate primary standards, whereas A. thaliana, Solanum lycopersicum and Pisum sativum were found to be the most suitable

The contribution of cytogenetics and flow cytometry for understanding the karyotype evolution in three Dorstenia (Linnaeus, 1753) species (Moraceae)

Chromosome morphometry and nuclear DNA content are useful data for cytotaxonomy and for understanding the evolutionary history of different taxa. However, the chromosome number is the only karyotype aspect reported for the species of Dorstenia so far. In this study, the nuclear genome size of Dorstenia arifolia (Lamarck, 1786), Dorstenia bonijesu (Carauta & C. Valente, 1983) and Dorstenia elata (Hooker, 1840) was evaluated and their karyotype morphometry accomplished, with the aim of verifying the potential of those parameters to understand evolutionary issues. Mean nuclear 2C value ranged from 2C = 3.49 picograms (pg) for Dorstenia elata to 2C = 5.47 pg for Dorstenia arifolia, a variation of ± 1.98 pg. Even though showing a marked difference in 2C value, the three species exhibited the same 2n = 32. Corroborating the flow cytometry data, differences in chromosome morphology were found among the karyotypes of the species investigated. Based on this and the only phylogeny proposed for Dorstenia thus far, structural rearrangements are related to the karyotype variations among the three species. Besides, the karyological analysis suggests a polyploid origin of the Dorstenia species studied here

In vitro responses in Passiflora species with different chromosome numbers, ploidy levels and nuclear 2C values: revisiting and providing new insights

Tissue culture in Passiflora has emerged as a strategy to propagate species with agronomic relevance, which is the main focus of most in vitro studies. Different morphogenic responses have been obtained under the same environmental in vitro conditions, mainly for species of the subgenus Passiflora with distinct 2n chromosome numbers. The aims of this study were to verify and compare the in vitro responses in Passiflora species with distinct 2n chromosome numbers, ploidy levels and nuclear 2C values. Under the same in vitro conditions, only friable calli occurred from mature zygotic embryo explants of Passiflora coriacea (2n = 2x = 12 chromosomes, 2C = 1.00 pg), Passiflora lindeniana (2n = 4x = 24, 2C = 2.42 pg) and Passiflora contracta (2n = 8x = 48, 2C = 4.78 pg). In contrast, plantlets were regenerated from Passiflora foetida (2n = 20, 2C = 1.04 pg) and Passiflora miniata (2n = 18, 2C = 3.40 pg) via indirect organogenesis and indirect somatic embryogenesis, respectively. By now, from mature zygotic embryo explants, de novo shoot organogenesis and somatic embryos have been recovered for Passiflora species with 2n = 18 chromosomes and relative high nuclear 2C value (more than 2C = 2.93 pg—Passiflora cincinata), and only de novo shoot organogenesis for P. foetida with 2n = 20 chromosomes and relative low 2C value (2C = 1.04 pg). Therefore, in a taxonomic and evolutive context, this study showed that the in vitro morphogenic pathways pretty varied between the Passiflora species with distinct karyotype features

Herbicide and Cytogenotoxic Activity of Inclusion Complexes of Psidium gaudichaudianum Leaf Essential Oil and β-Caryophyllene on 2-Hydroxypropyl-β-cyclodextrin

Funding Information: We would like to thank Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES), Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Fundação de Amparo à Pesquisa do Estado de Minas Gerais (FAPEMIG), and Fundação de Amparo à Pesquisa e Inovação do Espírito Santo (FAPES) for financial support. Publisher Copyright: © 2023 by the authors.The present investigation aimed to develop inclusion complexes (ICs) from Psidium gaudichaudianum (GAU) essential oil (EO) and its major compound β-caryophyllene (β-CAR), and to evaluate their herbicidal (against Lolium multiflorum and Bidens pilosa) and cytogenotoxic (on Lactuca sativa) activities. The ICs were obtained using 2-hydroxypropyl-β-cyclodextrin (HPβCD) and they were prepared to avoid or reduce the volatility and degradation of GAU EO and β-CAR. The ICs obtained showed a complexation efficiency of 91.5 and 83.9% for GAU EO and β-CAR, respectively. The IC of GAU EO at a concentration of 3000 µg mL−1 displayed a significant effect against weed species B. pilosa and L. multiflorum. However, the β-CAR IC at a concentration of 3000 µg mL−1 was effective only on L. multiflorum. In addition, the cytogenotoxic activity evaluation revealed that there was a reduction in the mitotic index and an increase in chromosomal abnormalities. The produced ICs were able to protect the EO and β-CAR from volatility and degradation, with a high thermal stability, and they also enabled the solubilization of the EO and β-CAR in water without the addition of an organic solvent. Therefore, it is possible to indicate the obtained products as potential candidates for commercial exploration since the ICs allow the complexed EO to exhibit a more stable chemical constitution than pure EO under storage conditions.publishersversionpublishe