Molecular phylogenetic study of flavonoids in medicinal plants: a case study family Apiaceae

Journal of Plant Research - The current study examined the phylogenetic pattern of medicinal species of the family Apiaceae based on flavonoid groups production, as well as the overall mechanism of...     

Evolution of the Portulaca oleracea L. aggregate in Egypt on molecular and phenotypic levels revealed by morphology,inter-simple sequence repeat (ISSR) and 18S rDNA gene sequence markers

Molecular markers including inter simple sequence repeats (ISSR) and 18S rDNA gene sequence markers were combined with a detailed morphological analysis to seek characters that discriminate four taxa of Portulaca oleracea s.l. These taxa were identified as the microspecies Portulaca nitida, Portulaca oleracea, Portulaca rausii and Portulaca granulatostellulata. Morphological characters did not provide a clear distinction among the four taxa of P. oleracea s.l. It was found that mixed populations of the taxa occur in several locations and morphological similarities between the microspecies were detected. ISSR analysis indicates that gene flow among populations of different taxa was high and most of the genetic variation (61.9%) occurs within population. These results are inconsistent with the general characteristics of P. oleracea as a self- or 5% cross-pollinated species. A close relationship between P. oleracea, P. rausii and P. granulatostellulata was supported by ISSR and 18S rDNA gene sequence. The ISSR and 18s data support the specific status of P. nitida as a recently evolved taxon. We conclude that P. oleracea exists as a polymorphic species and is not divisible into microspecies based on seed surface as the primary morphological trait, and inter simple sequence repeats (ISSR) and 18S rDNA gene sequence markers. We suggest that the taxa do not merit specific rank as morphological characters and absence of a breeding barrier fail to separate the different populations when they become sympatric.     

Titanium Dioxide Nanoparticles Affect the Percentage of Free Radical Scavenging,Protein Content and DNA Mismatch Repair Genes in <Emphasis Type="Italic">Zea mays</Emphasis> L. and <Emphasis Type="Italic">Triticum aestivum</Emphasis> L.

This paper identifies the potential molecular markers predicting the impact of nTiO₂ on plants and explores the new statistical correlations between the biomarkers and growth parameters. The quantitative mRNA expression of the three genes involved in DNA mismatch repair (MLH1) and cell division (PCNA1 and PCNA2) in Zea mays and Triticum aestivum seedlings were related to the growth parameters measured in response to five nTiO2 treatments. The results indicated that the higher concentrations were harmless to Z. mays but not to T. aestivum. nTiO₂ treatments increased the total protein levels in both species and significantly inhibited the percentage of DPPH radical scavenging in Z. mays compared with T. aestivum seedlings. The exposure to both 50 μg/ml and 30 μg/ml concentrations of nTiO₂ significantly induced the expression of MLH1 and PCNA1 genes in both species; however, the exposure to 30 μg/ml of nTiO₂ also significantly induced the expression of PCNA2 genes in T. aestivum. The exposure to 50, 70 and 140 μg/ml significantly inhibited the expression of PCNA2 in both species, while 70 and 140 μg/ml repressed the expression of MLH1 and PCNA1 in the seedlings of Z. mays. The induction and repression of the expression of the three genes were correlated with some growth parameters and biological indices in both species. This key finding suggests that the above genes may play a vital role in mediating plant stress response to nTiO₂ and could be used as sensitive molecular biomarkers indicative of the oxidative stress of nTiO₂ exposure.