The Allelochemical MDCA Inhibits Lignification and Affects Auxin Homeostasis

The phenylpropanoid 3,4-(methylenedioxy)cinnamic acid (MDCA) is a plant-derived compound first extracted from roots of Asparagus officinalis and further characterized as an allelochemical. Later on, MDCA was identified as an efficient inhibitor of 4-COUMARATE-CoA LIGASE (4CL), a key enzyme of the general phenylpropanoid pathway. By blocking 4CL, MDCA affects the biosynthesis of many important metabolites, which might explain its phytotoxicity. To decipher the molecular basis of the allelochemical activity of MDCA, we evaluated the effect of this compound on Arabidopsis thaliana seedlings. Metabolic profiling revealed that MDCA is converted in planta into piperonylic acid (PA), an inhibitor of CINNAMATE-4-HYDROXYLASE (C4H), the enzyme directly upstream of 4CL. The inhibition of C4H was also reflected in the phenolic profile of MDCA-treated plants. Treatment of in vitro grown plants resulted in an inhibition of primary root growth and a proliferation of lateral and adventitious roots. These observed growth defects were not the consequence of lignin perturbation, but rather the result of disturbing auxin homeostasis. Based on DII-VENUS quantification and direct measurement of cellular auxin transport, we concluded that MDCA disturbs auxin gradients by interfering with auxin efflux. In addition, mass spectrometry was used to show that MDCA triggers auxin biosynthesis, conjugation, and catabolism. A similar shift in auxin homeostasis was found in the c4h mutant ref3-2, indicating that MDCA triggers a cross talk between the phenylpropanoid and auxin biosynthetic pathways independent from the observed auxin efflux inhibition. Altogether, our data provide, to our knowledge, a novel molecular explanation for the phytotoxic properties of MDCA.Plants growing in a tight community are in continuous competition for space, light, water, and nutrients. Potential survival strategies include optimizing plant architecture and maximizing growth rate, allowing the plant to capture light and receive nutrients and water more efficiently, while placing neighboring plants in an unfavorable position (Einhellig, 1995; Weir et al., 2004). Besides developmental shifts, plants release an array of secondary metabolites (allelochemicals) into the rhizosphere to negatively affect the growth and reproduction of neighboring, competitor plants (Putnam, 1988; Bertin et al., 2003). Despite a lot of research effort having been devoted to allelopathic chemical warfare over the past decades, it remains a difficult study object due to the complexity of plant-plant interactions (Zeng, 2014). Nevertheless, the significance of allelochemicals in structuring plant communities and preserving biodiversity has been fully recognized by the scientific community. Moreover, allelochemicals show the potential to be used as an environmentally friendly alternative for weed control to improve agricultural productivity (Zeng, 2014).Strictly speaking, the term “allelochemical” refers to a compound produced and released by one organism to affect the growth and development of susceptible species (Weir et al., 2004). In practice, compounds derived from plant extracts or exudates are often cataloged as allelochemicals based on their inhibitory effect on seed germination and/or growth of other plant species in an artificial setup. Despite their importance, the molecular mode of action of a given allelochemical compound has rarely been studied in detail; however, toxicity is relatively easily demonstrated, identifying its molecular target is far more challenging. An interesting example is the phenylpropanoid 3,4-(methylenedioxy)cinnamic acid (MDCA), which was isolated from lyophilized root tissues of Asparagus [Asparagus officinalis L.; Hartung et al. (1990)]. It was suggested to be an allelochemical based on its inhibitory effect on root and shoot growth of Lepidium sativum (Hartung et al., 1990). Independent studies revealed that MDCA acts as an efficient competitive inhibitor of 4-COUMARATE-CoA LIGASE (4CL), the enzyme converting hydroxycinnamates to their corresponding CoA-esters (Knobloch and Hahlbrock, 1977; Chakraborty et al., 2009). This conversion is an early step in the general phenylpropanoid pathway leading to a wide array of metabolites, including coumarins, stilbenes, salicylic acid, flavonoids, and monolignols (Vogt, 2010). Given that inhibition of 4CL in this metabolic pathway will have far-reaching effects on plant growth and development (Voelker et al., 2010), it is tempting to link the proposed phytotoxicity of MDCA to this metabolic block.Here, we evaluate whether the phytotoxicity of MDCA is a direct consequence of the inhibition of 4CL or if MDCA targets also other biological processes in Arabidopsis (Arabidopsis thaliana). We found that MDCA causes strong developmental defects in Arabidopsis seedlings at early developmental stages. Convincing evidence was found that MDCA affects the homeostasis of the plant signaling compound auxin. Our results provide an alternative explanation for the molecular mechanism underlying the phytotoxic properties of MDCA, and suggest that these multiple modes of action make it an attractive candidate as an environmental agrochemical or synergist.     

Enhanced mutability at the tk locus in the radiosensitive double-strand break repair mutant xrs5

The thymidine kinase locus (tk) has been utilised as the target locus to measure the induced mutation frequency following X-irradiation in the X-ray-sensitive xrs5 mutant and its parent CHO K1 line of Chinese hamster cells. Mutations to tk- cells were measured by plating cells in selective medium containing trifluorothymidine after a post-irradiation expression time of 4 days. Our results show that the mutation frequency was 3-4 times higher in the xrs5 mutant than in the CHO K1 cell line. This enhanced mutation frequency in xrs5 is though to result from the deficiency in DNA double-strand break repair in this cell line which also results in the enhanced cell killing and higher frequencies of chromosomal aberrations in response to X-irradiation. The findings of the present study suggest that DNA double-strand break is a critical lesion leading to mutations in irradiated cells.     

Monoclonal antibody higher order structure analysis by high throughput protein conformational array

The elucidation of antibody higher order structure (HOS) is critical in therapeutic antibody development. Since HOS determines the protein bioactivity and chemo-physical properties, this knowledge can help to ensure that the safety and efficacy attributes are not compromised. Protein conformational array (PCA) is a novel method for determining the HOS of monoclonal antibodies. Previously, we successfully utilized an enzyme-linked immunosorbent assay (ELISA)-based PCA along with other bioanalytical tools to elucidate the structures of antibody aggregates. In this study, applying a new multiplex-based PCA with 48-fold higher throughput than the ELISA-based one we revealed structural differences between different antibody molecules and antibody structure changes affected by various processing conditions. The PCA analysis of antibody molecules clearly demonstrated significant differences between IgG1 and IgG4 subclasses in epitope exposure and folding status. Furthermore, we applied small angle X-ray scattering to decipher mechanistic insights of PCA technology and validate structural information obtained using PCA. These findings enhance our fundamental understanding of mAbs' HOS in general. The PCA analysis of antibody samples from various processing conditions also revealed that antibody aggregation caused significantly higher exposure of antibody epitopes, which potentially led to a “foreign” molecule that could cause immunogenicity. The PCA data correlated well with protein stability results from traditional methods such as size-exclusion chromatography and protein thermal shift assay. Our study demonstrated that high throughput PCA is a suitable method for HOS analysis in the discovery and development of therapeutic antibodies.     

Five years of antimalarial resistance marker surveillance in Gaza Province, Mozambique, following artemisinin-based combination therapy roll out

Antimalarial drug resistance is a major obstacle to malaria control and eventual elimination. The routine surveillance for molecular marker of resistance is an efficient way to assess drug efficacy, which remains feasible in areas where malaria control interventions have succeeded in substantially reducing malaria transmission. Community based asexual parasite prevalence surveys were conducted annually in sentinel sites in Gaza Province, Mozambique from 2006 until 2010, before, during and after antimalarial policy changes to artesunate plus sulfadoxine-pyrimethamine in 2006 and to artemether-lumefantrine in 2008. Genetic analysis of dhfr, dhps, crt, and mdr1 resistant genes was conducted on 3 331 (14.4%) Plasmodium falciparum PCR positive samples collected over the study period from 23 229 children aged 2 to 15 years. The quintuple dhfr/dhps mutation associated with sulfadoxine-pyrimethamine resistance increased from 56.2% at baseline to 75.8% by 2010. At baseline the crt76T and mdr186Y mutants were approaching fixation, 96.1% and 74.7%, respectively. Following the deployment of artemisinin-based combination therapy, prevalence of both these chloroquine-resistance markers began declining, reaching 32.4% and 30.9%, respectively, by 2010. All samples analysed over the 5-year period possessed a single copy of the mdr1 gene. The high and increasing prevalence of the quintuple mutation supports the change in drug policy from artesunate plus sulfadoxine-pyrimethamine to artemether-lumefantrine in Mozambique. As chloroquine related drug pressure decreased in the region, so did the molecular markers associated with chloroquine resistance (crt76T and mdr186Y). However, this reversion to the wild-type mdr186N predisposes parasites towards developing lumefantrine resistance. Close monitoring of artemether-lumefantrine efficacy is therefore essential, particularly given the high drug pressure within the region where most countries now use artemether-lumefantrine as first line treatment.     

Community knowledge and practices regarding malaria and long-lasting insecticidal nets during malaria elimination programme in an endemic area in Iran

A literature review for operational research on malaria control and elimination was conducted using the term 'malaria' and the definition of operational research (OR). A total of 15 886 articles related to malaria were searched between January 2008 and June 2013. Of these, 582 (3.7%) met the definition of operational research. These OR projects had been carried out in 83 different countries. Most OR studies (77%) were implemented in Africa south of the Sahara. Only 5 (1%) of the OR studies were implemented in countries in the pre-elimination or elimination phase. The vast majority of OR projects (92%) were led by international or local research institutions, while projects led by National Malaria Control Programmes (NMCP) accounted for 7.8%. With regards to the topic under investigation, the largest percentage of papers was related to vector control (25%), followed by epidemiology/transmission (16.5%) and treatment (16.3%). Only 19 (3.8%) of the OR projects were related to malaria surveillance. Strengthening the capacity of NMCPs to conduct operational research and publish its findings, and improving linkages between NMCPs and research institutes may aid progress towards malaria elimination and eventual eradication world-wide.     

Aminolipids elicit functional trade-offs between competitiveness and bacteriophage attachment in Ruegeria pomeroyi

Lipids play a crucial role in maintaining cell integrity and homeostasis with the surrounding environment. Cosmopolitan marine roseobacter clade (MRC) and SAR11 clade bacteria are unique in that, in addition to glycerophospholipids, they also produce an array of amino acid-containing lipids that are conjugated with beta-hydroxy fatty acids through an amide bond. Two of these aminolipids, the ornithine aminolipid (OL) and the glutamine aminolipid (QL), are synthesized using the O-acetyltransferase OlsA. Here, we demonstrate that OL and QL are present in both the inner and outer membranes of the Gram-negative MRC bacterium Ruegeria pomeroyi DSS-3. In an olsA mutant, loss of these aminolipids is compensated by a concurrent increase in glycerophospholipids. The inability to produce aminolipids caused significant changes in the membrane proteome, with the membrane being less permeable and key nutrient transporters being downregulated while proteins involved in the membrane stress response were upregulated. Indeed, the import of ¹⁴C-labelled choline and dimethylsulfoniopropionate, as a proxy for the transport of key marine nutrients across membranes, was significantly impaired in the olsA mutant. Moreover, the olsA mutant was significantly less competitive than the wild type (WT) being unable to compete with the WT strain in co-culture. However, the olsA mutant unable to synthesize these aminolipids is less susceptible to phage attachment. Together, these data reveal a critical role for aminolipids in the ecophysiology of this important clade of marine bacteria and a trade-off between growth and avoidance of bacteriophage attachment.Subject terms: Ecology, Microbiology     

Artificial ossification of muscular flap after plastic surgery of the bone cavity under the effect of electric current

Experiments in rabbits revealed that transplantation of a muscular flap on the central feeding pedicle in the tibis medullary canal and its electro-stimulation with direct microelectric current of 18-20 muA with the alternating polarity speeded up the process of reorganization of the muscular flap in the depth of which new osseous tissue was forming. Electrostimulation of osteogenesis in case of the muscular plastic transplantation promotes restoration of the anatomic integrity of the bone.