Antimicrobial peptides as effective tools for enhanced disease resistance in plants

Plant Cell, Tissue and Organ Culture (PCTOC) - Four serotypes of the dengue virus that can cause severe disease in humans greatly increases the complexity of vaccine development. In this study, we...     

Postbiotics as potential promising tools for SARS-CoV-2 disease adjuvant therapy

The SARS-CoV-2 pandemic defines the global health tension of our time. There are several continuous efforts to find a definitive cure in this regard. According to some adverse effects and problems of customary SARS-CoV-2 disease therapies, bioactive compounds, for example probiotics-derived metabolites (postbiotics) have been accomplishing supreme importance by investigators for adjuvant cures in patients with SARS-CoV-2. Postbiotics inhibit angiotensin-converting enzyme 2 activity and stimulate the immune system. They also boost the SARS-CoV-2 disease treatment effectiveness and reduce its adverse effects in SARS-CoV-2 illness patients as a result of antiviral and anti-inflammatory effects. Furthermore, postbiotics having unique features such as high safety, high shelf life and stability to the gastrointestinal tract can be utilized as hopeful instruments for both adjuvant and inhibition strategies in SARS-CoV-2 patients with no earnest unfavourable adverse effects. The concept of postbiotics and their biocompatible characteristics are comprehensively discussed in the present review while highlighting the bilateral relationship between postbiotic biometabolites and respiratory tract infection with a special look at the potential biological role in the inactivation of SARS-CoV-2 and reduction of related inflammatory pathways.     

Pterostilbene fluorescent probes as potential tools for targeting neurodegeneration in biological applications

Several epidemiological studies suggest that a diet rich in fruit and vegetables reduces the incidence of neurodegenerative diseases. Resveratrol (Res) and its dimethylated metabolite, pterostibene (Ptb), have been largely studied for their neuroprotective action. The clinical use of Res is limited because of its rapid metabolism and its poor bioavailability. Ptb with two methoxy groups and one hydroxyl group has a good membrane permeability, metabolic stability and higher in vivo bioavailability in comparison with Res. The metabolism and pharmacokinetics of Ptb are still sparse, probably due to the lack of tools that allow following the Ptb destiny both in living cells and in vivo. In this contest, we propose two Ptb fluorescent derivatives where Ptb has been functionalised by benzofurazan and rhodamine-B-isothiocyanate, compounds 1 and 2, respectively. Here, we report the synthesis, the optical and structural characterisation of 1 and 2, and, their putative cytotoxicity in two different cell lines.     

Mapping and diagnostic marker development for Soil-borne cereal mosaic virus resistance in bread wheat

Monogenically-inherited resistance to Soil-borne cereal mosaic virus (SBCMV) in hexaploid bread wheat cultivars ‘Tremie’ and ‘Claire’ was mapped on chromosome 5D. The two closest flanking markers identified in the Claire-derived mapping population, Xgwm469-5D and E37M49, are linked to the resistance locus at distances of 1 and 9 cm, respectively. Xgwm469-5D co-segregated with the SBCMV resistance in the Tremie-derived population and with the recently identified Sbm1 locus in the cv. Cadenza. This suggested that Tremie and Claire carry a resistance gene allelic to Sbm1, or one closely linked to it. The diagnostic value of Xgwm469-5D was assessed using a collection of SBCMV resistant and susceptible cultivars. Importantly, all susceptible genotypes carried a null allele of Xgwm469-5D, whereas resistant genotypes presumably related to either Claire and Tremie or Cadenza revealed a 152 or 154 bp allele of Xgwm469-5D, respectively. Therefore, Xgwm469-5D is well suited for marker assisted selection for SBCMV resistance.     

Chromatin modification acts as a memory for systemic acquired resistance in the plant stress response

Priming of defence genes for amplified response to secondary stress can be induced by application of the plant hormone salicylic acid or its synthetic analogue acibenzolar S‐methyl. In this study, we show that treatment with acibenzolar S‐methyl or pathogen infection of distal leaves induce chromatin modifications on defence gene promoters that are normally found on active genes, although the genes remain inactive. This is associated with an amplified gene response on challenge exposure to stress. Mutant analyses reveal a tight correlation between histone modification patterns and gene priming. The data suggest a histone memory for information storage in the plant stress response.     

Biotechnological potential of engineering pathogen effector proteins for use in plant disease management

A key component in the management of many diseases of crops is the use of plant disease resistance genes. However, the discovery and then sequence identification of these plant genes is challenging, whereas the characterization of the molecules that they recognize, the effector/avirulence products in pathogens, is often considerably more straight forward. Effectors are small proteins secreted by pathogens that can play major roles in modulating a plant's defense against attack. Effectors can be used to guide breeding of resistance genes, to trigger defense responses, and are part of integrated disease management strategies for crop protection. This review covers the role of effector-driven biotechnology in controlling plant diseases caused by fungi or oomycetes. Given that multi-billion dollar agriculture crops are based in some cases on plants recognizing just a handful of such effector proteins, there is considerable scope to use more fully effector proteins as a biotechnology resource in agriculture.     

T-DNA tagging in Brassica napus as an efficient tool for the isolation of new promoters for selectable marker genes

A simple strategy to identify and isolate new promoters suitable for driving the expression of selectable marker genes is described. By employing a Brassica napus hypocotyl transformation protocol and a promoterless gus::nptII tagging construct, a series of 20 kanamycin-resistant tagged lines was produced. Most of the regenerated plants showed hardly any GUS activity in leaf, stem and root tissues. However, expression was readily restored in callus tissue induced on in vitro leaf segments. Genomic sequences upstream of the gus::nptII insertions were isolated via plasmid rescue. Three clones originating from single copy T-DNA lines were selected for further evaluation. The rescued plasmids were cloned as linear fragments in binary vectors and re-transformed to Brassica napus hypocotyl and Solanum tuberosum stem segments. The new sequences maintained their promoter activity, demonstrated by transient and stable GUS activity after transformation. Furthermore, the promoters provided sufficient expression of the nptII gene to yield transgenic plants when using kanamycin as selective agent. Database searching (BLASTN) revealed that the promoters have significant homology with three Arabidopsis BAC clones, one Arabidopsis cDNA and one Brassica napus cDNA. The results presented in this paper illustrate the strength of combined methods for identification, isolation and testing of new plant promoters.     

Mislocalization of large ARF-GEFs as a potential mechanism for BFA resistance in COG-deficient cells

Defects in subunits of the conserved oligomeric Golgi (COG) complex represent a growing subset of congenital disorders of glycosylation (CDGs). In addition to altered protein glycosylation and vesicular trafficking, Cog-deficient patient fibroblasts exhibit a striking delay in the Golgi-disrupting effects of brefeldin A (BFA). Despite the diagnostic value of this BFA resistance, the molecular basis of this response is not known. To investigate potential mechanisms of resistance, we analyzed the localization of the large ARF-GEF, GBF1, in several Cog-deficient cell lines. Our results revealed mislocalization of GBF1 to non-Golgi compartments, in particular the ERGIC, within these cells. Biochemical analysis of GBF1 in control and BFA-treated fibroblasts demonstrated that the steady-state level and membrane recruitment is not substantially affected by COG deficiency, supporting a role for the COG complex in the localization but not membrane association of GBF1. We also showed that pretreatment of fibroblasts with bafilomycin resulted in a GBF1-independent BFA resistance that appears additive with the resistance associated with COG deficiency. These data provide new insight into the mechanism of BFA resistance in Cog-deficient cells by suggesting a role for impaired ARF-GEF localization.     

Evaluating the Madeiran wheat germplasm for aluminum resistance using aluminium-induced callose formation in root apices as a marker

Aluminum (Al) resistance of 57 Madeiran wheat cultivars was evaluated using callose content in root tips and root elongation as markers. Al induced callose formation was a very sensitive indicator of Al damage detecting wide range of genotypic differences existing in the Madeiran wheat germplasm. A weak, yet positive correlation (R²=0.285, P<0.05) between callose content and root elongation was found.     

The potential of hydroxamic acids in tetraploid and hexaploid wheat varieties as resistance factors against the bird‐cherry oat aphid,Rhopalosiphum padi

The potential for exploiting natural wheat resistance to control the cereal aphid Rhopalosiphum padi, the most important aphid pest of small grain cereals in the UK, was investigated as an alternative approach to the use of insecticides. The investigation focussed on a group of secondary metabolites, the hydroxamic acids or benzoxazinones, present naturally as glucosides, but which hydrolyse on tissue damage to give biologically active aglycones, e.g. 2,4‐dihydroxy‐7‐methoxy‐1,4‐benzoxazin‐3‐one (DIMBOA) which are associated with natural plant defence. These can be important for resistance against insects, fungi, bacteria and nematodes for a range of cultivated monocotyledonous plants and could ultimately be combined with other defence mechanisms to provide a general approach to cereal aphid control. Levels of hydroxamic acids, particularly DIMBOA‐glucoside, were determined in hexaploid (Triticum aestivum) and tetraploid (Triticum durum) wheat varieties and differences were found between species and varieties. The effect of feeding by R. padi on the level of hydroxamic acids in the leaf tissue was also investigated. Thus, after 24 h of aphid feeding, as an apparently localised hydrolytic defence reaction in the leaf, levels of DIMBOA‐glucoside decreased noticeably. When aphids were fed on sucrose solution containing low doses of DIMBOA there was a significant mortality compared to the sucrose control. However, the levels of and variation in hydroxamic acids in the wheat varieties investigated were insufficient for significant differences in aphid behaviour and development.     

Genetic variants in a lipid regulatory pathway as potential tools for improving the nutritional quality of grass‐fed beef

The aim of this study was to evaluate the effect of genetic variants on candidate genes corresponding to the sterol recognition element–binding protein‐1 (SREBP‐1) signaling pathway and stearoyl‐CoA desaturases (SCD1 and SCD5) on muscle fatty acid (FA) composition of Brangus steers fattened on grass. FA profiles were measured on Longissimus lumborum muscle samples using a gas chromatography–flame ionization detection technique. A total of 43 tag single‐nucleotide polymorphisms on the SCD1, SCD5, SREBP‐1, SCAP, INSIG1, INSIG2, MBTPS1, MBTPS2, and SRPR genes were genotyped on 246 steers to perform a marker–trait association study. To evaluate the influence of the Indicine breed in the composite breed, additional groups of 48 Angus, 18 Hereford, 75 Hereford x Angus, and 36 Limousin x Hereford–Angus steers were also genotyped. To perform the association analysis, FA data were grouped according to the number of carbon atoms and/or number of double bonds (i.e. SFA, MUFA, PUFA, etc.). In addition, different indexes that reflect the activity of FA desaturase and elongase enzymes were calculated. SCD1 markers significantly affected C14:1/(C14:0 + C14:1) and C18:1/(C18:0 + C18:1) indexes, whereas one SNP in SCD5 was correlated with the C16:1/(C16:0 + C16:1) index. Polymorphisms in the signal recognition particle receptor (SRPR) gene were associated with all the estimated desaturase indexes. Because the evaluated markers showed no effect on total lipid content of beef, this work supports the potential utilization of these markers for the improvement of grass‐fed beef without undesirable side effects.