The biosynthesis of flavonoid glycosides and their importance in chemosystematics

The present article reviews flavonoid O-glycosyltransferases with respect to the historical background, isolation and purification methods, properties of the enzymes involved (especially substrate specificities) and genetic control. The possible biosynthetic pathway leading to the formation of C-glycosides is also discussed. The second part of the article is an attempt to indicate the importance of glycosylation patterns in the field of chemosystematics, especially on the intra- and infra-specific levels. The position and nature of glycosylation are first discussed, and this is followed by examples indicating the importance of glycosylation patterns.     

Targeted Proteomics for Studying Pathogenic Bacteria

Mass spectrometry‐based proteomics has been extensively used to map bacterial proteomes, which has led to a better understanding of the molecular mechanisms underlying bacterial infection and bacteria–host interactions. Quantitative proteomics using selected or parallel reaction monitoring is considered one of the most sensitive and specific quantitative MS‐based approaches and has significantly advanced proteome studies of pathogenic bacteria. Here, recent applications of targeted proteomics for bacteria identification, biomarker discovery, and the characterization of bacterial virulence and antimicrobial resistance are reviewed among others. Results of such studies are expected to further contribute to improve the fight against the most common human pathogenic bacteria.     

Ester- and amide-containing multiQACs: Exploring multicationic soft antimicrobial agents

Quaternary ammonium compounds (QACs) are ubiquitous antiseptics whose chemical stability is both an aid to prolonged antibacterial activity and a liability to the environment. Soft antimicrobials, such as QACs designed to decompose in relatively short times, show the promise to kill bacteria effectively but not leave a lasting footprint. We have designed and prepared 40 soft QAC compounds based on both ester and amide linkages, in a systematic study of mono-, bis-, and tris-cationic QAC species. Antimicrobial activity, red blood cell lysis, and chemical stability were assessed. Antiseptic activity was strong against a panel of six bacteria including two MRSA strains, with low micromolar activity seen in many compounds; amide analogs showed superior activity over ester analogs, with one bisQAC displaying average MIC activity of ～1 μM. For a small subset of highly bioactive compounds, hydrolysis rates in pure water as well as buffers of pH = 4, 7, and 10 were tracked by LCMS, and indicated good stability for amides while rapid hydrolysis was observed for all compounds in acidic conditions.     

The genetics underlying metabolic signatures in a brown rice diversity panel and their vital role in human nutrition

Brown rice (Oryza sativa) possesses various nutritionally dense bioactive phytochemicals exhibiting a wide range of antioxidant, anti-cancer, and anti-diabetic properties known to promote various human health benefits. However, despite the wide claims made about the importance of brown rice for human nutrition the underlying metabolic diversity has not been systematically explored. Non-targeted metabolite profiling of developing and mature seeds of a diverse genetic panel of 320 rice cultivars allowed quantification of 117 metabolites. The metabolite genome-wide association study (mGWAS) detected genetic variants influencing diverse metabolic targets in developing and mature seeds. We further interlinked genetic variants on chromosome 7 (6.06–6.43 Mb region) with complex epistatic genetic interactions impacting multi-dimensional nutritional targets, including complex carbohydrate starch quality, the glycemic index, antioxidant catechin, and rice grain color. Through this nutrigenomics approach rare gene bank accessions possessing genetic variants in bHLH and IPT5 genes were identified through haplotype enrichment. These variants were associated with a low glycemic index, higher catechin levels, elevated total flavonoid contents, and heightened antioxidant activity in the whole grain with elevated anti-cancer properties being confirmed in cancer cell lines. This multi-disciplinary nutrigenomics approach thus allowed us to discover the genetic basis of human health-conferring diversity in the metabolome of brown rice.     

Molecular evolution of Cinetochilum and Sathrophilus (Protozoa,Ciliophora, Oligohymenophorea), two genera of ciliates with morphological affinities to scuticociliates

Zhang, Q., Miao, M., Strüder‐Kypke, M. C., Al‐Rasheid, K. A. S., Al‐Farraj, S. A. & Song, W. (2011). Molecular evolution of Cinetochilum and Sathrophilus (Protozoa, Ciliophora, Oligohymenophorea), two genera of ciliates with morphological affinities to scuticociliates. —Zoologica Scripta, 40, 317–325. The ciliate order Loxocephalida sensu Li et al. (2006) has been considered to be systematically uncertain within the subclass Scuticociliatia. Loxocephalids display mixed morphological features and morphogenetic patterns that are found in two different oligohymenophorean subclasses: scuticociliates and hymenostomes. To reveal their phylogenetic positions, molecular information on this group is urgently needed but still inadequate. In the present study, we have sequenced the small subunit rRNA gene of two newly described loxocephalids, Cinetochilum ovale Gong & Song 2008; and Sathrophilus planus Fan et al. 2010; which have never been discussed based on molecular analysis. Results show: (i) all phylogenetic trees are nearly identical in placing Cinetochilum closest to the subclass Apostomatia and form a monophyletic group divergent from the typical scuticociliates, (ii) the genus Sathrophilus, together with Anoplophrya, a poorly known Astomatia, forms a peripheral branch separated from the scuticociliatian assemblage and (iii) the affiliation of the loxocephalid genera sensu Li et al. (2006) is not confirmed due to a dispersion in four deeply diverged clades. In addition, the polyphyly of the genus Cyclidium, shown in previous studies, is confirmed by our phylogenetic analyses and supported by the approximately unbiased test based on the new database in this work.     

Three-dimensional multicellular cell culture for anti-melanoma drug screening: focus on tumor microenvironment

AbstractThe development of new treatments for malignant melanoma, which has the worst prognosis among skin neoplasms, remains a challenge. The tumor microenvironment aids tumor cells to grow and resist to chemotherapeutic treatment. One way to mimic and study the tumor microenvironment is by using three-dimensional (3D) co-culture models (spheroids). In this study, a melanoma heterospheroid model composed of cancer cells, fibroblasts, and macrophages was produced by liquid-overlay technique using the agarose gel. The size, growth, viability, morphology, cancer stem-like cells population and inflammatory profile of tumor heterospheroids and monospheroids were analyzed to evaluate the influence of stromal cells on these parameters. Furthermore, dacarbazine cytotoxicity was evaluated using spheroids and two-dimensional (2D) melanoma model. After finishing the experiments, it was observed the M2 macrophages induced an anti-inflammatory microenvironment in heterospheroids; fibroblasts cells support the formation of the extracellular matrix, and a higher percentage of melanoma CD271 was observed in this model. Additionally, melanoma spheroids responded differently to the dacarbazine than the 2D melanoma culture as a result of their cellular heterogeneity and 3D structure. The 3D model was shown to be a fast and reliable tool for drug screening, which can mimic the in vivo tumor microenvironment regarding interactions and complexity.Graphic abstract