Root anatomy of some species of Amaranthus (Amaranthaceae) and formation of successive cambia

El-Ghamery, Abbas A.; Sadek, Ahmed M.; Elbar, Ola H. Abd

doi:10.1016/j.aoas.2015.03.001

Cited by 13 publications

(9 citation statements)

References 17 publications

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“…The secondary structures of roots and stems observed in G. marginata show an unusual or anomalous thickening of the vascular cylinder due to the high activity of supernumerary cambia, resulting specially in the formation of abundant reserve tissues. This anomalous thickening is a common phenomenon in the Amaranthaceae (Metcalfe and Chalk, 1950; Menezes et al, 1969; Grosso, 2007; El-Ghamery et al, 2015; Sá et al, 2016) and Chenopodiaceae (Metcalfe and Chalk, 1950; Krumbiegel, 1998). In G. albiflora , root secondary growth was also considered atypical (Jáuregui et al, 2014) as the authors showed that the successive rings are formed from a lateral meristem producing parenchyma outward, supernumerary cambia and parenchyma inward.…”

Section: Discussionmentioning

confidence: 99%

Chemical Structure and Localization of Levan, the Predominant Fructan Type in Underground Systems of Gomphrena marginata (Amaranthaceae)

et al. 2018

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Gomphrena marginata Seub. (Amaranthaceae) is an endemic species from Brazilian campos rupestres with a fructan accumulating underground reserve system. Analyses of high performance anion exchange chromatography (HPAEC–PAD) revealed the presence of the soluble carbohydrates glucose, fructose, sucrose, 1-kestose, 6-kestose, nystose and fructans with degree of polymerization (DP) up to approximately 40 fructose units. Data of 1H and 13C Nuclear Magnetic Resonance (NMR) spectroscopy, including Heteronuclear Single-Quantum Correlation (HSQC) and Heteronuclear Multiple-Bonds Correlation (HMBC) showed the presence of β (2,6) linkages, characteristic of the linear molecule of levan-type fructan(2,6). These results confirmed previous studies suggesting that the reserve carbohydrate in the underground system of this species was levan-type fructans, similar to that of G. macrocephala. Structural analyses of the thickened underground system using light microscopy revealed a mixed origin system consisting mainly of a gemmiferous tuberous root with the upper region formed by short branched stems, both presenting vascular cylinders with unusual growth patterns. Fructan spherocrystals were visualized under polarized light and scanning electron microscopy (SEM) mostly in the cortex and vascular cylinder in both thickened stem and root. In addition to data reported in the literature concerning the occurrence of fructans in the Amaranthaceae, the results presented here suggest that fructans are a trait in this family while the levan-type fructan prevail in Gomphrena species.

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Section: Discussionmentioning

confidence: 99%

Chemical Structure and Localization of Levan, the Predominant Fructan Type in Underground Systems of Gomphrena marginata (Amaranthaceae)

et al. 2018

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“…(2001) studied pollen variations, Adhikary and Pratt (2015) analysed pollen and floral variations within various species, and El-Ghamery et al . (2015) studied the root anatomies of 12 Amaranthus taxa.…”

Section: Introductionmentioning

confidence: 99%

Comparative analysis of the complete chloroplast genome sequences of three Amaranthus species

Hong

Cheon

Yoo

et al. 2019

Plant Genet. Resour.

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The complete chloroplast (cp) genome sequences of three Amaranthus species (Amaranthus hypochondriacus, A. cruentus and A. caudatus) were determined by next-generation sequencing. The cp genome sequences of A. hypochondriacus, A. cruentus and A. caudatus were 150,523, 150,757 and 150,523 bp in length, respectively, each containing 84 genes with identical contents and orders. Expansion or contraction of the inverted repeat region was not observed among the three Amaranthus species. The coding regions were highly conserved with 99.3% homology in nucleotide and amino acid sequences. Five genes – matK, accD, ndhJ, ccsA and ndhF – showed relatively high non-synonymous/synonymous values (Ka/Ks > 0.1). Sequence comparison identified two insertion/deletion (InDels) greater than 40 bp in length, and polymerase chain reaction markers that could amplify these InDel regions were applied to diverse Korean Genbank accessions, which could discriminate the three Amaranthus species. Phylogenetic analyses based on 62 protein-coding genes showed that the core Caryophyllales were monophyletic and Amaranthoideae formed a sister group with the Betoideae and Chenopodioideae clade. Comparing each homologous locus among the three Amaranthus species, identified eight regions with high Pi values (>0.03). Seven of these loci, except for rps19-trnH (GUG), were considered to be useful molecular markers for further phylogenetic studies.

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“…(A) Segment at the transition zone had GC 1 assigned to the main stem with three smaller stems that were not present in the above segments. EVANS: GROWTH CENTERS IN STEMS Rajput et al 2012, Abd Elbar 2015, El-Ghamery et al 2015, Pace et al 2018, Myskow et al 2019. Schenk (1999) reviewed mechanisms and patterns of axis splits and described the ecological functions of clonal splits in desert shrubs.…”

Section: Materials and Methods Sample Collectionmentioning

confidence: 99%

“…Plants exhibit many anatomical anomalies during secondary growth (Duff and Nolan 1953, Newman 1956, Esau 1965, Dobbins 1971, Fahn 1974, Mauseth 1988, Schweingruber et al 2006, Mauseth 2014). Examples of anomalies resulting from secondary growth caused by abnormal cambia include the formation of successive cambia (Fahn and Zimmerman 1982, Terazas 1991, Carlquist 2007, Rajput et al 2012, Abd Elbar 2015, El-Ghamery et al 2015, Pace et al 2018, Myskow et al 2019, regenerating cambia (Steward et al 1958, Gautheret 1959, Wilson and Wilson 1961, differential production of secondary tissues (Dobbins 1971, Horak 1981, supernumerary cambia (Kirchoff and Fahn 1984), fasciations caused by unusual cambium development (Albertson et al 1983, Tang andKnap 1998), cresting growths of cactus stem terminals (Thornton 2007), unequal cambial activity (Ayensa andStern 1964, Jones andLord 1982), and wood eccentricities (Diettert 1938;Ferguson and Humphrey 1959;Ferguson 1964;Evans et al 2019;Scarinci et al 2017;Evans and Graney 2018;Evans 2021a, b). Anomalous cambia produce xylem and phloem cells, but may also produce a variety of cell types (Newman 1956, Dobbins 1971.…”

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confidence: 99%

Production of growth centers in stems of three shrub species1

Evans

2022

The Journal of the Torrey Botanical Society

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Shrubs are dominant plants in many hot deserts with limited moisture throughout the world. Shrubs are woody plants of relatively low height, distinguished from trees by having several stems rather than a single trunk. Soon after seedling establishment, main stems of shrubs produce a large number of growth centers that produce independent stems. The purpose of this study is to describe the characteristics of growth centers in stems responsible for the production of independent stems in three desert shrub species. Samples were processed from the transition zone to about 30 mm above the transition zone. Axis splits and lobes were common in the three species. Growth centers were identified as areas of concentric circles of xylem cells. Concentric circles of xylem cells can only be produced by cambial cells. In some cases, axis splits directly fractured the vascular cambium to produce fragmented cambia to produce growth centers. In other tissues, axis splits were not visible but growth centers developed. Lobes may move cambial cells that may have temporarily ceased activity but may become active at a later date and begin producing cells to become growth centers. These cambial cells are from a fragmented cambium that have moved to various locations by axis splits and lobes. To our knowledge, this is the first study to describe the process of producing fragmented cambia in shrub species in tandem with axis splits and eccentric growth (lobes) of stems. Moreover, this is the first study to document the production of individual stems from individual fragmented cambia.

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Root anatomy of some species of Amaranthus (Amaranthaceae) and formation of successive cambia

Cited by 13 publications

References 17 publications

Chemical Structure and Localization of Levan, the Predominant Fructan Type in Underground Systems of Gomphrena marginata (Amaranthaceae)

Chemical Structure and Localization of Levan, the Predominant Fructan Type in Underground Systems of Gomphrena marginata (Amaranthaceae)

Comparative analysis of the complete chloroplast genome sequences of three Amaranthus species

Production of growth centers in stems of three shrub species1

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