Correction to: Managing biological invasions: the cost of inaction

Biological Invasions -     

Transient Exposure of Enalapril Normalizes Prenatal Programming of Hypertension and Urinary Angiotensinogen Excretion

Maternal low protein diet programs offspring to develop hypertension as adults. Transient exposure to angiotensin converting enzyme inhibitors or angiotensin II receptor blockers can result in improvement in hypertension. Male rats whose mothers received a low protein diet during the last half of pregnancy were given either vehicle, continuous enalapril (CE) in their drinking water or were given transient enalapril exposure (TE) after weaning at 21 days of age. The TE group had enalapril in their drinking water for 21 days starting from day 21 of life. All rats were studied at 6 months of age. Vehicle treated rats whose mothers were fed a low protein diet were hypertensive, had albuminuria, and demonstrated upregulation of the intrarenal renin-angiotensin system as evidenced by higher urinary angiotensinogen and urinary angiotensin II levels. In low protein rats both continuous and transient exposure to enalapril normalized blood pressure, urinary angiotensinogen and urinary angiotensin II levels at 6 months of age, but only continuous administration of enalapril decreased urinary albumin excretion. These data support the importance of the intrarenal renin-angiotensin system in mediating hypertension in programmed rats and transient exposure to enalapril can reprogram the hypertension and dysregulation of the intrarenal renin-angiotensin system.     

Enhanced tolerance to salinity following cellular acclimation to increasing NaCl levels in Medicago truncatula

Salinity is a major abiotic stress that limits plant productivity. Plants respond to salinity by switching on a coordinated set of physiological and molecular responses that can result in acclimation. Medicago truncatula is an important model legume species, thus understanding salt stress responses and acclimation in this species is of both fundamental and applied interest. The aim of this work was to test whether acclimation could enhance NaCl tolerance in calli of M. truncatula. A new protocol is described incorporating multi-step up acclimation over 0–350 mM exogenous NaCl. By the end of the experiment, calli were tolerant to 150 mM and competent for embryogenesis at 100 mM NaCl. Positive and negative linear relationships between Na⁺ and K⁺ uptake and exogenous NaCl concentration intercepted at 160 mM suggesting a Na⁺/K⁺ homeostasis. Proline level peaked at 100/150 mM whilst highest osmolarity and lowest water content occurred at 250/350 mM NaCl. The concentration of water soluble sugars was positively related to 0–250 mM NaCl whilst callus growth and embryogenesis occurred regardless of endoreduplication. Expression of genes linked to growth (WEE1), in vitro embryogenesis (SERK), salt tolerance (SOS1), proline synthesis (P5CS) and ploidy level (CCS52 and WEE1) peaked at 100/150 mM NaCl. Hence, these genes and various physiological traits except sugar levels, served as useful markers of NaCl tolerance. To our knowledge, this is the first report of a multi-step acclimation conferring tolerance to 150 mM NaCl in leaf-derived calli of M. truncatula.     

Wet fractionation of the succulent halophyte Salicornia sinus-persica,with the aim of low input (water saving) biorefining into bioethanol

In this study Salicornia sinus-persica, a succulent halophyte was assessed for its potential to be used as a feedstock for bioethanol production. For such succulent, salty, green biomasses, direct fractionation and fermentation allow for water preservation in the process. Fresh biomass of S. sinus-persica was collected and split into two fractions by wet fractionation; liquid (juice) and solid (pulp). Sugar contents were found to be 1.0–1.5% for the juice fraction and 50% (w/w) for the fresh pulp. Direct fermentation of the juice using Saccharomyces cerevisiae showed no salt inhibition of the yeast and ethanol yields of ~70% were achieved. A pretreatment study was carried out for the pulp fraction applying mild hydrothermal pretreatment. Cellulose convertibility was found to be significantly higher for severity factors above 2.00, and the highest ethanol yield (76.91 ± 3.03%) was found at process severity of 3.06 (170 °C, 10 min).

     

Isoenzymes and flow cytometry for the assessment of true-to-typeness of calluses and cell suspensions of barrel medic prior to regeneration

A successful exploitation of in vitro tools for breeding and for the understanding of gene functioning requires the regeneration of true-to-type plants and experiments were therefore performed with several genotypes of Medicago truncatula (J5, TRV25, TR122) to characterize mother plants and regenerating tissues. Each sample was assessed by flow cytometry and, whatever the genotype and regeneration pathway, a divergent phenotype was systematically linked to an abnormal nuclear DNA content. All samples assessed were classed according to their flow cytometry profiles into normal (true-to-type) material, aneuploids, endoreduplicated tissues, tetraploids, mixoploids and senescent tissues. Deviating calluses failed to regenerate or gave rise to infertile, non-viable plants. In turn, all tissues with non true-to-type flow cytometry profiles were examined in terms of isoenzyme banding patterns compared to the mother plants. Esterases, Peroxidases and Leucine aminopeptidase appeared to be the best isozyme systems to show differences between the original genotypes but also between diverging materials and the mother plants. Interestingly, such differences were more often qualitative (presence or absence of bands) than quantitative (i.e. differences in colour intensity of bands) thereby making easier an accurate distinction between genotypes. Peroxidases were prone to variation with culture medium and tissue age. The results stressed the importance of using more than one approach when undertaking the characterisation of materials as, for some of the genotypes analysed, differences compared to the respective mother plants could be shown with flow cytometry that were not reflected in a different banding pattern with isoenzymes.     

Role of bone marrow derived-mesenchymal stem cells against gastric ulceration: Histological,immunohistochemical and ultrastructural study

The current study aimed to assess the antiulcerogenic impact of mesenchymal bone marrow stem cells (BMMSCs) against gastric ulcer induced by the use of piroxicam in rats and to compare this effect with the antiulcer drug “Pantoloc ®” proton pump inhibitors. The study included histological, histochemical, immunohistochemical and ultrastructural examination in stomach of rats in different study groups. In the ulcerated group, the glandular region of the stomach displayed clear mucosal lesions occurring as perforations along the stomach axis. In addition, stomach displayed degeneration of surface mucous cells accompanied by pyknosis, vacuolation among parietal cells in ishmus region, basal region with vacuolated chief cells and karyolitic nucleus of parietal cells. Moreover, Stomach sections of ulcer model rats showed intensive immunoreactivity to cytokeratin 20, Cox 2 and PCNA. Findings of the present study have shown that BMMSCs have an ameliorative effect against piroxicam-induced gastric ulcer in rats. Collectively, the proposed work has shown that BMMSCs have a curative capacity as an antiulcer due to their high antioxidant activity. Further studies are required in molecular levels to understand the mechanism of action during treatment.     

Indole glucosinolates exhibit anti-inflammatory effects on Ehrlich ascites carcinoma cells through modulation of inflammatory markers and miRNAs

Molecular Biology Reports - Nuclear factor-κB (NF-κB) has been identified as the major link between inflammation and cancer. Natural agents that inhibit this pathway are essential in...     

Ketogenic Diet in Cancer Prevention and Therapy: Molecular Targets and Therapeutic Opportunities

Although cancer is still one of the most significant global challenges facing public health, the world still lacks complementary approaches that would significantly enhance the efficacy of standard anticancer therapies. One of the essential strategies during cancer treatment is following a healthy diet program. The ketogenic diet (KD) has recently emerged as a metabolic therapy in cancer treatment, targeting cancer cell metabolism rather than a conventional dietary approach. The ketogenic diet (KD), a high-fat and very-low-carbohydrate with adequate amounts of protein, has shown antitumor effects by reducing energy supplies to cells. This low energy supply inhibits tumor growth, explaining the ketogenic diet’s therapeutic mechanisms in cancer treatment. This review highlights the crucial mechanisms that explain the ketogenic diet’s potential antitumor effects, which probably produces an unfavorable metabolic environment for cancer cells and can be used as a promising adjuvant in cancer therapy. Studies discussed in this review provide a solid background for researchers and physicians to design new combination therapies based on KD and conventional therapies.