Differences in the Structural Chemical Composition of the Primary Xylem of Cactaceae: A Topochemical Perspective

Maceda, Agustín; Soto-Hernández, Marcos; Peña-Valdivia, Cecilia B.; Trejo, Carlos; Terrazas, Teresa

doi:10.3389/fpls.2019.01497

Cited by 12 publications

(18 citation statements)

References 147 publications

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“…Other compounds were detected by this technique located in the phellem of C. pentandra ( Figure S2 , C ), the presence of channels with autofluorescent compounds in blue and green tones corresponded to terpenes and flavonoids, [16] whose presence in the cortex has been reported for this species [34] . Finally, the fluorescence emission in cyan tones of starch granules in P. chrysacanthus was similar to that reported by Maceda et al [13] . in seedlings of L. lychnidiflora , therefore, the combination of this conventional staining method with epifluorescence allowed to identify the presence of starch granules in plant tissues.…”

Section: Discussionsupporting

confidence: 86%

“…Epifluorescence microscopy: The fluorescence of the analyzed tissues can vary depending on the sample preparation such as pH or concentration of the reagents, the thickness of the tissue, the presence or absence of autofluorescence of the components, the interaction between dyes, and the excitation wavelengths. [14,16] Therefore, in order to make qualitative comparisons of the different species analyzed, this staining was based on the results obtained by De Micco and Aronne [15] and Maceda et al [13] with safranin O/fast green combined with epifluorescence microscopy, as mentioned below.…”

Section: Methodsmentioning

confidence: 99%

“…When comparing epifluorescence with bright-field microscopy (Figure 2 -4), the results obtained with the safranine O/fast green staining method were of better quality and allowed to identify in detail the differences in the composition of the xylem cells, similar to that reported by different authors. [13,15,30] De Micco and Aronne [15] proposed that the use of safranin O/fast green staining allowed the detection of both the fluorescence of lignin caused by the staining and its autofluorescence, blue tones were related to the presence of syringyl/guaiacyl, while tones close to red could be related to the presence of guaiacyl. [15] Similarly, Bond et al [17] mentioned that fluorescence emission caused by safranin O staining occurred in the range of 488 to 568 nm and Angeles et al [30] detected the lignin fluorescence in the range of 505 to 530 nm with the same staining method.…”

Section: Lignin Distributionmentioning

confidence: 99%

“…The first studies on the chemical composition of Cactaceae stems focused on Opuntia ficus-indica due to its importance in human consumption, [10] as fodder, [11] and more recently, its potential in the paper industry. [12] The chemical composition of secondary [4,5] and primary xylem [13] has been calculated for some species belonging to Pereskioideae, Opuntioideae, and Cactoideae subfamilies.…”

Section: Introductionmentioning

confidence: 99%

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Distribution and Chemical Composition of Lignin in Secondary Xylem of Cactaceae

Maceda

Reyes-Rivera

Soto-Hernández

et al. 2021

Chemistry & Biodiversity

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Cactaceae family has heterogeneity in the accumulation of lignocellulose due to the diversity of shapes and anatomy of the wood. Most studies focus on fibrous and dimorphic species; but the non‐fibrous species are poorly studied. The aims of this work were to analyze the syringyl/guaiacyl ratio of lignin and its distribution in secondary xylem, especially in non‐fibrous species. The syringyl/guaiacyl (S/G) ratio was quantified from 34 species of cacti by nitrobenzene oxidation of free‐extractive wood. The distribution of lignocellulose in wood sections stained with safranin O/fast green was determined with epifluorescence microscopy. The S/G ratio was heterogeneous; most of the non‐fibrous species had a higher percentage of syringyl, while the fibrous ones accumulate guaiacyl. Fluorescence emission showed that vessel elements and wide‐band tracheids had similar tonalities. It is hypothesized that the presence of a higher percentage of syringyl in most cacti is part of the defense mechanism against pathogens, which together with the succulence of the stem represent adaptations that contribute to survival in their hostile environments.

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Section: Discussionsupporting

confidence: 86%

Section: Methodsmentioning

confidence: 99%

Section: Lignin Distributionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Distribution and Chemical Composition of Lignin in Secondary Xylem of Cactaceae

Maceda

Reyes-Rivera

Soto-Hernández

et al. 2021

Chemistry & Biodiversity

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“…Wide-band trachieds are a special type of tracheid with no perforations on their walls but instead possessing rigid secondary thickening bands ( Mauseth, 1999 ). A region of WBTs was reported in several species of cacti, including in Melocactus zehntneri and Melocactus bahiensis ( Mauseth et al, 1995 ; Mauseth and Plemons-Rodriguez, 1997 ; Mauseth, 1999 ; Stone-Palmquist and Mauseth, 2002 ; Arruda et al, 2004 ; Mauseth, 2004 ; Arruda et al, 2005 ; Mauseth, 2006 ; Melo-de-Pinna et al, 2006 ; Vázquez-Sánchez et al, 2007 ; Arruda and Melo-de-Pinna, 2010 ; Terrazas et al, 2016 ; Reyes-Rivera et al, 2018 ; Maceda et al, 2019 ). The paucity of support elements ( i.e.…”

Section: Discussionmentioning

confidence: 99%

Anatomy, Flow Cytometry, and X-Ray Tomography Reveal Tissue Organization and Ploidy Distribution in Long-Term In Vitro Cultures of Melocactus Species

et al. 2020

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Cacti have a highly specialized stem that enables survival during extended dry periods. Despite the ornamental value of cacti and the fact that stems represent the main source of explants in tissue culture, there are no studies on their morpho-anatomical and cytological characteristics in Melocactus . The present study seeks to address the occurrence of cells with mixed ploidy level in cacti tissues. Specifically, we aim to understand how Melocactus stem tissue is organized, how mixoploidy is distributed when present, and whether detected patterns of ploidy change after long periods of in vitro culture. To analyze tissue organization, Melocactus glaucescens and Melocactus paucispinus plants that had been germinated and cultivated in vitro were analyzed for stem structure using toluidine blue, Xylidine Ponceau, Periodic Acid Schiff, ruthenium red, and acid floroglucin. To investigate patterns of ploidy, apical, medial, and basal zones of the stem, as well as, periphery, cortex, and stele (vascular tissue and pith) regions of the stem and root apexes from four- and ten-year old cultured in vitro were analyzed by flow cytometry. X-ray micro-computed tomography (XRµCT) was performed with fragments of stems from both species. The scarcity of support elements ( i.e. , sclereids and fibers) indicates that epidermis, hypodermis, and wide-band tracheids present in cortical vascular bundles and stele, as well as water stored in aquifer parenchyma cells along the cortex, provide mechanical support to the stem. Parenchyma cells increase in volume with a four-fold increase in ploidy. M. glaucescens and M. paucispinus exhibit the same pattern of cell ploidy irrespective of topophysical region or age, but there is a marked difference in ploidy between the stem periphery (epidermis and hypodermis), cortex, stele, and roots. Mixoploidy in Melocactus is not related to the age of the culture, but is a developmental trait, whereby endocycles promote cell differentiation to accumulate valuable water.

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