Establishment of a conditional Nomo1 mouse model by CRISPR/Cas9 technology

Molecular Biology Reports - The Nomo1 gene mediates a wide range of biological processes of importance in embryonic development. Accordingly, constitutive perturbation of Nomo1 function may result...     

Uncertainty quantification and sensitivity analysis of COVID-19 exit strategies in an individual-based transmission model

Many countries are currently dealing with the COVID-19 epidemic and are searching for an exit strategy such that life in society can return to normal. To support this search, computational models are used to predict the spread of the virus and to assess the efficacy of policy measures before actual implementation. The model output has to be interpreted carefully though, as computational models are subject to uncertainties. These can stem from, e.g., limited knowledge about input parameters values or from the intrinsic stochastic nature of some computational models. They lead to uncertainties in the model predictions, raising the question what distribution of values the model produces for key indicators of the severity of the epidemic. Here we show how to tackle this question using techniques for uncertainty quantification and sensitivity analysis. We assess the uncertainties and sensitivities of four exit strategies implemented in an agent-based transmission model with geographical stratification. The exit strategies are termed Flattening the Curve, Contact Tracing, Intermittent Lockdown and Phased Opening. We consider two key indicators of the ability of exit strategies to avoid catastrophic health care overload: the maximum number of prevalent cases in intensive care (IC), and the total number of IC patient-days in excess of IC bed capacity. Our results show that uncertainties not directly related to the exit strategies are secondary, although they should still be considered in comprehensive analysis intended to inform policy makers. The sensitivity analysis discloses the crucial role of the intervention uptake by the population and of the capability to trace infected individuals. Finally, we explore the existence of a safe operating space. For Intermittent Lockdown we find only a small region in the model parameter space where the key indicators of the model stay within safe bounds, whereas this region is larger for the other exit strategies.     

Molecular and Biochemical Characterization of a β-Fructofuranosidase from Xanthophyllomyces dendrorhous

An extracellular β-fructofuranosidase from the yeast Xanthophyllomyces dendrorhous was characterized biochemically, molecularly, and phylogenetically. This enzyme is a glycoprotein with an estimated molecular mass of 160 kDa, of which the N-linked carbohydrate accounts for 60% of the total mass. It displays optimum activity at pH 5.0 to 6.5, and its thermophilicity (with maximum activity at 65 to 70°C) and thermostability (with a T₅₀ in the range 66 to 71°C) is higher than that exhibited by most yeast invertases. The enzyme was able to hydrolyze fructosyl-β-(2→1)-linked carbohydrates such as sucrose, 1-kestose, or nystose, although its catalytic efficiency, defined by the k_cat/K_m ratio, indicates that it hydrolyzes sucrose approximately 4.2 times more efficiently than 1-kestose. Unlike other microbial β-fructofuranosidases, the enzyme from X. dendrorhous produces neokestose as the main transglycosylation product, a potentially novel bifidogenic trisaccharide. Using a 41% (wt/vol) sucrose solution, the maximum fructooligosaccharide concentration reached was 65.9 g liter⁻¹. In addition, we isolated and sequenced the X. dendrorhous β-fructofuranosidase gene (Xd-INV), showing that it encodes a putative mature polypeptide of 595 amino acids and that it shares significant identity with other fungal, yeast, and plant β-fructofuranosidases, all members of family 32 of the glycosyl-hydrolases. We demonstrate that the Xd-INV could functionally complement the suc2 mutation of Saccharomyces cerevisiae and, finally, a structural model of the new enzyme based on the homologous invertase from Arabidopsis thaliana has also been obtained.The basidiomycetous yeast Xanthophyllomyces dendrorhous (formerly Phaffia rhodozyma) produces astaxanthin (3-3′-dihydroxy-β,β-carotene-4,4 dione [17, 25]). Different industries have displayed great interest in this carotenoid pigment due to its attractive red-orange color and antioxidant properties, which has intensified the molecular and genetic study of this yeast. As a result, several genes involved in the astaxanthin biosynthetic pathway have been cloned and/or characterized, as well as some other genes such as those encoding actin (60), glyceraldehyde-3-phosphate dehydrogenase (56), endo-β-1,3-glucanase, and aspartic protease (4). In terms of the use of carbon sources, a β-amylase (9), and an α-glucosidase (33) with glucosyltransferase activity (12), as well as a yeast cell-associated invertase (41), have also been reported.Invertases or β-fructofuranosidases (EC 3.2.1.26) catalyze the release of β-fructose from the nonreducing termini of various β-d-fructofuranoside substrates. Yeast β-fructofuranosidases have been widely studied, including that of Saccharomyces cerevisiae (11, 14, 45, 46), Schizosaccharomyces pombe (36), Pichia anomala (40, 49), Candida utilis (5, 8), or Schwanniomyces occidentalis (2). They generally exhibit strong similarities where sequences are available, and they have been classified within family 32 of the glycosyl-hydrolases (GH) on the basis of their amino acid sequences. The catalytic mechanism proposed for the S. cerevisiae enzyme implies that an aspartate close to the N terminus (Asp-23) acts as a nucleophile, and a glutamate (Glu-204) acts as the acid/base catalyst (46). In addition, the three-dimensional structures of some enzymes in this family have been resolved, such as that of an exoinulinase from Aspergillus niger (var. awamori; 37) and the invertase from Arabidopsis thaliana (55).As well as hydrolyzing sucrose, β-fructofuranosidases from microorganisms may also catalyze the synthesis of short-chain fructooligosaccharides (FOS), in which one to three fructosyl moieties are linked to the sucrose skeleton by different glycosidic bonds depending on the source of the enzyme (3, 52). FOS are one of the most promising ingredients for functional foods since they act as prebiotics (44), and they exert a beneficial effect on human health, participating in the prevention of cardiovascular diseases, colon cancer, or osteoporosis (28). Currently, Aspergillus fructosyltransferase is the main industrial producer of FOS (15, 52), producing a mixture of FOS with an inulin-type structure, containing β-(2→1)-linked fructose-oligomers (¹F-FOS: 1-kestose, nystose, or ¹F-fructofuranosylnystose). However, there is certain interest in the development of novel molecules that may have better prebiotic and physiological properties. In this context, β-(2→6)-linked FOS, where this link exits between two fructose units (⁶F-FOS: 6-kestose) or between fructose and the glucosyl moiety (⁶G-FOS: neokestose, neonystose, and neofructofuranosylnystose), may have enhanced prebiotic properties compared to commercial FOS (29, 34, 54). The enzymatic synthesis of 6-kestose and other related β-(2→6)-linked fructosyl oligomers has already been reported in yeasts such as S. cerevisiae (11) or Schwanniomyces occidentalis (2) and in fungi such as Thermoascus aurantiacus (26) or Sporotrichum thermophile (27). However, the production of FOS included in the ⁶G-FOS series has not been widely reported in microorganisms, probably because they are not generally produced (2, 15) or because they represent only a minor biosynthetic product (e.g., with baker''s yeast invertase) (11). Most research into neo-FOS production has been carried out with Penicillium citrinum cells (19, 31, 32, 39). In this context, neokestose is the main transglycosylation product accumulated by whole X. dendrorhous cells from sucrose (30), although the enzyme responsible for this reaction remained uncharacterized.Here, we describe the molecular, phylogenetic, and biochemical characterization of an extracellular β-fructofuranosidase from X. dendrorhous. Kinetic studies of its hydrolytic activity were performed using different substrates, and we investigated its fructosyltransferase capacity. The functionality of the gene analyzed was verified through its heterologous expression, and a structural model of this enzyme based on the homologous invertase from A. thaliana has also been obtained.     

Structural and Molecular Basis of the Peroxynitrite-mediated Nitration and Inactivation of Trypanosoma cruzi Iron-Superoxide Dismutases (Fe-SODs) A and B: DISPARATE SUSCEPTIBILITIES DUE TO THE REPAIR OF TYR35 RADICAL BY CYS83 IN Fe-SODB THROUGH INTRAMOLECULAR ELECTRON TRANSFER*

Trypanosoma cruzi, the causative agent of Chagas disease, contains exclusively iron-dependent superoxide dismutases (Fe-SODs) located in different subcellular compartments. Peroxynitrite, a key cytotoxic and oxidizing effector biomolecule, reacted with T. cruzi mitochondrial (Fe-SODA) and cytosolic (Fe-SODB) SODs with second order rate constants of 4.6 ± 0.2 × 10⁴ m⁻¹ s⁻¹ and 4.3 ± 0.4 × 10⁴ m⁻¹ s⁻¹ at pH 7.4 and 37 °C, respectively. Both isoforms are dose-dependently nitrated and inactivated by peroxynitrite. Susceptibility of T. cruzi Fe-SODA toward peroxynitrite was similar to that reported previously for Escherichia coli Mn- and Fe-SODs and mammalian Mn-SOD, whereas Fe-SODB was exceptionally resistant to oxidant-mediated inactivation. We report mass spectrometry analysis indicating that peroxynitrite-mediated inactivation of T. cruzi Fe-SODs is due to the site-specific nitration of the critical and universally conserved Tyr³⁵. Searching for structural differences, the crystal structure of Fe-SODA was solved at 2.2 Å resolution. Structural analysis comparing both Fe-SOD isoforms reveals differences in key cysteines and tryptophan residues. Thiol alkylation of Fe-SODB cysteines made the enzyme more susceptible to peroxynitrite. In particular, Cys⁸³ mutation (C83S, absent in Fe-SODA) increased the Fe-SODB sensitivity toward peroxynitrite. Molecular dynamics, electron paramagnetic resonance, and immunospin trapping analysis revealed that Cys⁸³ present in Fe-SODB acts as an electron donor that repairs Tyr³⁵ radical via intramolecular electron transfer, preventing peroxynitrite-dependent nitration and consequent inactivation of Fe-SODB. Parasites exposed to exogenous or endogenous sources of peroxynitrite resulted in nitration and inactivation of Fe-SODA but not Fe-SODB, suggesting that these enzymes play distinctive biological roles during parasite infection of mammalian cells.     

Size-selective dispersal of Daphnia resting eggs by backswimmers (Notonecta maculata)

Freshwater zooplankton is increasingly used to study effects of dispersal on community and metacommunity structure. Yet, it remains unclear how zooplankton disperses. Clearly, birds and wind play a significant role as zooplankton dispersal agents, but they may not always be the main vectors. This experimental study shows that a cosmopolitan aquatic insect, Notonecta, can be an important vector of cladoceran resting eggs (ephippia). Dispersing Notonecta frequently transported ephippia during flight, with a bias towards smaller ephippia in two species. A similar trend was present at the species level: Daphnia species with smaller ephippia were more often dispersed, suggesting that Notonecta could generate specific colonist communities. In addition, buoyancy appeared a critical trait, as non-floating ephippia of Daphnia magna were never dispersed. Our data suggest that Notonecta could be important dispersers of Daphnia, and that knowledge of dispersal dynamics of Notonecta may be used to predict Daphnia dispersal, colonization and resilience to disturbance.     

Discrete forms of amylose are synthesized by isoforms of GBSSI in pea

Amyloses with distinct molecular masses are found in the starch of pea embryos compared with the starch of pea leaves. In pea embryos, a granule-bound starch synthase protein (GBSSIa) is required for the synthesis of a significant portion of the amylose. However, this protein seems to be insignificant in the synthesis of amylose in pea leaves. cDNA clones encoding a second isoform of GBSSI, GBSSIb, have been isolated from pea leaves. Comparison of GBSSIa and GBSSIb activities shows them to have distinct properties. These differences have been confirmed by the expression of GBSSIa and GBSSIb in the amylose-free mutant of potato. GBSSIa and GBSSIb make distinct forms of amylose that differ in their molecular mass. These differences in product specificity, coupled with differences in the tissues in which GBSSIa and GBSSIb are most active, explain the distinct forms of amylose found in different tissues of pea. The shorter form of amylose formed by GBSSIa confers less susceptibility to the retrogradation of starch pastes than the amylose formed by GBSSIb. The product specificity of GBSSIa could provide beneficial attributes to starches for food and nonfood uses.     

AMPK activation restores the stimulation of glucose uptake in an in vitro model of insulin-resistant cardiomyocytes via the activation of protein kinase B

Diabetic hearts are known to be more susceptible to ischemic disease. Biguanides, like metformin, are known antidiabetic drugs that lower blood glucose concentrations by decreasing hepatic glucose production and increasing glucose disposal in muscle. Part of these metabolic effects is thought to be mediated by the activation of AMP-activated protein kinase (AMPK). In this work, we studied the relationship between AMPK activation and glucose uptake stimulation by biguanides and oligomycin, another AMPK activator, in both insulin-sensitive and insulin-resistant cardiomyocytes. In insulin-sensitive cardiomyocytes, insulin, biguanides and oligomycin were able to stimulate glucose uptake with the same efficiency. Stimulation of glucose uptake by insulin or biguanides was correlated to protein kinase B (PKB) or AMPK activation, respectively, and were additive. In insulin-resistant cardiomyocytes, where insulin stimulation of glucose uptake was greatly reduced, biguanides or oligomycin, in the absence of insulin, induced a higher stimulation of glucose uptake than that obtained in insulin-sensitive cells. This stimulation was correlated with the activation of both AMPK and PKB and was sensitive to the phosphatidylinositol-3-kinase/PKB pathway inhibitors. Finally, an adenoviral-mediated expression of a constitutively active form of AMPK increased both PKB phosphorylation and glucose uptake in insulin-resistant cardiomyocytes. We concluded that AMPK activators, like biguanides and oligomycin, are able to restore glucose uptake stimulation, in the absence of insulin, in insulin-resistant cardiomyocytes via the additive activation of AMPK and PKB. Our results suggest that AMPK activation could restore normal glucose metabolism in diabetic hearts and could be a potential therapeutic approach to treat insulin resistance.     

Activated T cells complicate the identification of regulatory T cells in rheumatoid arthritis

Most cell surface markers for CD4⁺CD25⁺ regulatory T cells (Tregs) are also expressed by activated non-regulatory T cells. Recently, CD127 down-regulation was found to identify functional Tregs in healthy individuals, but there are no data from patients with inflammatory conditions. We examined peripheral blood mononuclear cells (PBMC) from rheumatoid arthritis patients with active inflammation and from healthy controls, and found that CD4⁺ T cells contained an equal proportion of CD25⁺CD127⁻/low cells in both groups. In patients, not all these cells expressed intracellular FOXP3. Upon activation by anti-CD3/anti-CD28, PBMC rapidly down-regulated CD127, while FOXP3 up-regulation was transitory and occurred in fewer cells. The activated cells were not anergic to restimulation and had no suppressive effects. The distinct kinetics indicate that the FOXP3⁻CD127⁻/low cells in rheumatoid arthritis patients most likely represent activated non-regulatory T cells. This complicates the use of CD127 for identification of Tregs in inflammatory diseases.