Multiomics reveals glutathione metabolism as a driver of bimodality during stem cell aging

With age, skeletal muscle stem cells (MuSCs) activate out of quiescence more slowly and with increased death, leading to defective muscle repair. To explore the molecular underpinnings of these defects, we combined multiomics, single-cell measurements, and functional testing of MuSCs from young and old mice. The multiomics approach allowed us to assess which changes are causal, which are compensatory, and which are simply correlative. We identified glutathione (GSH) metabolism as perturbed in old MuSCs, with both causal and compensatory components. Contrary to young MuSCs, old MuSCs exhibit a population dichotomy composed of GSHhigh cells (comparable with young MuSCs) and GSHlow cells with impaired functionality. Mechanistically, we show that antagonism between NRF2 and NF-κB maintains this bimodality. Experimental manipulation of GSH levels altered the functional dichotomy of aged MuSCs. These findings identify a novel mechanism of stem cell aging and highlight glutathione metabolism as an accessible target for reversing MuSC aging.

Fasting induces a highly resilient deep quiescent state in muscle stem cells via ketone body signaling

Short-term fasting is beneficial for the regeneration of multiple tissue types. However, the effects of fasting on muscle regeneration are largely unknown. Here, we report that fasting slows muscle repair both immediately after the conclusion of fasting as well as after multiple days of refeeding. We show that ketosis, either endogenously produced during fasting or a ketogenic diet or exogenously administered, promotes a deep quiescent state in muscle stem cells (MuSCs). Although deep quiescent MuSCs are less poised to activate, slowing muscle regeneration, they have markedly improved survival when facing sources of cellular stress. Furthermore, we show that ketone bodies, specifically β-hydroxybutyrate, directly promote MuSC deep quiescence via a nonmetabolic mechanism. We show that β-hydroxybutyrate functions as an HDAC inhibitor within MuSCs, leading to acetylation and activation of an HDAC1 target protein p53. Finally, we demonstrate that p53 activation contributes to the deep quiescence and enhanced resilience observed during fasting.

Exercise rejuvenates quiescent skeletal muscle stem cells in old mice through restoration of Cyclin D1

Aging impairs tissue repair. This is pronounced in skeletal muscle, whose regeneration by muscle stem cells (MuSCs) is robust in young adult animals but inefficient in older organisms. Despite this functional decline, old MuSCs are amenable to rejuvenation through strategies that improve the systemic milieu, such as heterochronic parabiosis. One such strategy, exercise, has long been appreciated for its benefits on healthspan, but its effects on aged stem cell function in the context of tissue regeneration are incompletely understood. Here we show that exercise in the form of voluntary wheel running accelerates muscle repair in old animals and improves old MuSC function. Through transcriptional profiling and genetic studies, we discovered that the restoration of old MuSC activation ability hinges on restoration of Cyclin D1, whose expression declines with age in MuSCs. Pharmacologic studies revealed that Cyclin D1 maintains MuSC activation capacity by repressing TGFβ signaling. Taken together, these studies demonstrate that voluntary exercise is a practicable intervention for old MuSC rejuvenation. Furthermore, this work highlights the distinct role of Cyclin D1 in stem cell quiescence.

Discrimination of epimeric glycans and glycopeptides using IM-MS and its potential for carbohydrate sequencing

Mass spectrometry is the primary analytical technique used to characterize the complex oligosaccharides that decorate cell surfaces. Monosaccharide building blocks are often simple epimers, which when combined produce diastereomeric glycoconjugates indistinguishable by mass spectrometry. Structure elucidation frequently relies on assumptions that biosynthetic pathways are highly conserved. Here, we show that biosynthetic enzymes can display unexpected promiscuity, with human glycosyltransferase pp-α-GanT2 able to utilize both uridine diphosphate N-acetylglucosamine and uridine diphosphate N-acetylgalactosamine, leading to the synthesis of epimeric glycopeptides in vitro. Ion-mobility mass spectrometry (IM-MS) was used to separate these structures and, significantly, enabled characterization of the attached glycan based on the drift times of the monosaccharide product ions generated following collision-induced dissociation. Finally, ion-mobility mass spectrometry following fragmentation was used to determine the nature of both the reducing and non-reducing glycans of a series of epimeric disaccharides and the branched pentasaccharide Man3 glycan, demonstrating that this technique may prove useful for the sequencing of complex oligosaccharides.

Structure and biological activity of chemically modified nisin A species

Nisin, a 34-residue peptide bacteriocin, contains the less common amino acids lanthionine, beta-methyl-lanthionine, dehydroalanine (Dha), and dehydrobutyrine (Dhb). Several chemically modified nisin A species were purified by reverse-phase HPLC and characterized by two-dimensional NMR and electrospray mass spectrometry. Five constituents, [2-hydroxy-Ala5]nisin, [Ile4-amide,pyruvyl-Leu6]des-Dha5-nisin, [Met(O)21]nisin, [Ser33]nisin, and nisin-(1-32)-peptide amide, were found in a commercial nisin sample. A further species, [2-hydroxy-Ala5]nisin-(1-32)-peptide amide, was obtained by freeze drying an acidic nisin solution. These compounds are formed by chemical modification of nisin: the addition of a water molecule to the dehydroalanine residues, which can lead to the cleavage of the polypeptide chain, or the oxidation of methionine residues. The 2-hydroxyalanine-containing products have a limited stability; they are spontaneously converted into the corresponding des-dehydroalanine derivatives. The growth-inhibiting activity of the modified nisins towards different bacteria was determined. The 2-hydroxyalanine-containing species and the des-dehydroalanine derivative show a strong reduction in biological activity as compared to native nisin. [Met(O)21]nisin and [Ser33]nisin show moderate or no reduction in biological activity.

Improvement of solubility and stability of the antimicrobial peptide nisin by protein engineering

Nisin is a 3.4-kDa antimicrobial peptide that, as a result of posttranslational modifications, contains unsaturated amino acids and lanthionine residues. It is applied as a preservative in various food products. The solubility and stability of nisin and nisin mutants have been studied. It is demonstrated that nisin mutants can be produced with improved functional properties. The solubility of nisin A is highest at low pH values and gradually decreases by almost 2 orders of magnitude when the pH of the solution exceeds a value of 7. At low pH, nisin Z exhibits a decreased solubility relative to that of nisin A; at neutral and higher pH values, the solubilities of both variants are comparable. Two mutants of nisin Z, which contain lysyl residues at positions 27 and 31, respectively, instead of Asn-27 and His-31, were produced with the aim of reaching higher solubility at neutral pH. Both mutants were purified to homogeneity, and their structures were confirmed by one- and two-dimensional 1H nuclear magnetic resonance. Their antimicrobial activities were found to be similar to that of nisin Z, whereas their solubilities at pH 7 increased by factors of 4 and 7, respectively. The chemical stability of nisin A was studied in the pH range of 2 to 8 and at a 20, 37, and 75 degrees C. Optimal stability was observed at pH 3.0. Nisin Z showed a behavior similar to that of nisin A. A mutant containing dehydrobutyrine at position 5 instead of dehydroalanine had lower activity but was significantly more resistant to acid-catalyzed chemical degradation than wild-type nisin Z.

Pharmacokinetic studies of hematoporphyrin derivatives on rat hepatocytes. Protoporphyrin dimethyl ester hematoporphyrin ether versus dihematoporphyrin ether-free hematoporphyrin derivative

Rat liver cells incorporate monomeric as well as dimeric hematoporphyrin derivatives. Time-dependent incubation assays gave evidence that monomeric compounds are more efficiently incorporated compared to protoporphyrin dimethyl ester hematoporphyrin ether. HL60 cells take up dimeric porphyrins in substantially higher quantities than hepatocytes do. These results allow the conclusion that physiological versus tumor cells behave differently with respect to porphyrin uptake: Whereas physiological cells prefer monomeric porphyrins, tumor cells preferentially incorporate dimeric porphyrins.

Pharmacokinetic and -dynamic investigations on HL60 cells with a new protoporphyrin dimethyl ester hematoporphyrin dimer

Pharmacokinetic and -dynamic studies using a novel porphyrin dimer were performed in human line HL60 promyelocytic leukemia cells. Uptake of the dimer into leukemic cells was observed to occur at substantially lower concentrations in comparison to a previously described monomeric dihematoporphyrin ether-free hematoporphyrin derivative. Both dimer and monomer derivatives could be demonstrated to inhibit cell growth, with no remarkable quantitative differences being found in cell proliferation studies regarding [3H]-thymidine incorporation and assay for colony formation. Structurally, the new compound represents an unsymmetrically substituted diethyl ether having protoporphyrin dimethyl ester and hematoporphyrin as substituents. For this reason the compound was designated as protoporphyrin dimethyl ester hematoporphyrin ether.

[Rotor syndrome: relevance of the determination of coproporphyrin isomers in the urine in comparison with intrahepatic (alcohol-induced) cholestasis]

Porphyrin isomer examinations have been performed in two patients with Rotor syndrome (RS), one patient with Gilbert-Meulengracht syndrome and 12 patients with alcohol toxic cholestasis. Under both conditions, cholestasis and RS, total urinary coproporphyrin excretion as well as coproporphyrin isomer I was relatively and absolutely increased. Despite the different degree of the increase of coproporphyrin isomer I excretion between RS (69 vs. 72%) and cholestasis (47% on average), there are single cases with a coproporphyrin isomer I portion around 60%. In such cases, the differential diagnosis is quite difficult, so that the diagnosis "Rotor syndrome" should never be gained by one distinct examination; it is a diagnosis performed by exclusion of other diseases.

On the preparation of dihematoporphyrin ether-free hematoporphyrin derivative

A dihematoporphyrin ether-free hematoporphyrin derivative has been prepared by a base-catalysed dehydration of hematoporphyrin with sodium hydroxide. The identification was performed by HPLC and mass spectroscopy (FD-MS). The reaction of hematoporphyrin with 1 M sodium hydroxide for 24 h yields more than 90% of the monomeric porphyrins.

Purification and some physicochemical properties of bovine kappa-casein

1. A description is given of the fractionation of kappa-casein on DEAE-cellulose using a pH gradient. With this method an improved separation of the kappa-casein components with a higher negative charge is obtained. 2. It is shown that at least one of the kappa-casein fractions has a second phosphate ester group. The heterogeneity of kappa-casein therefore is not exclusively caused by a varying N-acetylneuraminic acid content. 3. Ultracentrifuge experiments and exclusion gel chromatography show that the purified kappa-casein fraction having the lowest electrophoretic mobility exhibits a monomer-polymer association equilibrium. The free energy of association per mol monomer in 0.2 M NaCl is approximately --36 kJ-mol-1.