Enzyme In Pathway Research Articles

Identification of a higher C-S lyase activity of Staphylococcus hominis in volunteers with unpleasant axillary odour.

Excessive and unpleasant odours that emanate from the skin can induce bromhidrosis and substantially impair a person's quality of life. Enzymatic pathways generating unpleasant odours are well detailed, and among them, the C-S lyase is one of the enzymes involved in the conversion of non-volatile precursors into thiol-type malodorous volatile molecules such as 3M3SH. This study aimed to investigate the variation of axillary odour intensity correlated with Staphylococcus (S.) hominis C-S lyase activity within a group of volunteers after a physical activity. First, a group of 24 volunteers from the same ethnicity with standardized hygienic and alimentary practices participated in a supervised indoor cycling activity. Following this session, worn T-shirts were recovered to enable the olfactory evaluation of axillary odours by qualified experts. To go further, the microbiota from the axillary zone of each volunteer was sampled and the bacterial relative abundance was investigated by using 16S rRNA metasequencing. Then, S. hominis isolates were obtained by culturomics from these microbiota samples and the C-S lyase activity was measured by spectrofluorometry in protein crude extracts. The evaluation of the odour intensity revealed that within the panel, two groups were significantly distinct. A non-odorous group and a malodorous one with volunteers having unpleasant odours. The 16S rRNA metasequencing reveals differences in bacterial communities between the two groups with a significant increase in the relative abundance of S. hominis in the malodorous group compared with the non-odorous one. The C-S lyase activities measured on S. hominis sampled on volunteers from the two groups demonstrate that for an equivalent quantity of protein, this enzymatic activity is significantly higher for the samples originating from the malodorous group. Hence, this study demonstrates that beyond the increase of S. hominis relative abundance, the C-S lyase enzymatic activity of this bacteria is also higher in volunteers with unpleasant axillary odours.

The Role of Hydroxyeicosatetraenoic Acids in the Regulation of Inflammation in Bronchial Asthma.

Hydroperoxyeicosatetraenoic acids (HETEs) are metabolites of arachidonic acid that are oxidized by a family of enzymes including cyclooxygenase, lipoxygenase, and cytochrome P450 enzymes. These enzymes are widely present in various organs and tissues, and the HETEs they synthesize perform an important function in the regulation of immune reactions and haemostasis processes under physiological and pathophysiological conditions. More researchers confirm the role of these oxidized metabolites in modulating inflammation in asthma. The high production of HETEs in allergic and severe asthma indicates their involvement in the processes of an acute inflammatory response. On the other hand, disturbance of the metabolic transformation of arachidonic acid contributes to the development of chronic inflammation due to insufficient synthesis of mediators that resolve inflammatory processes. Several HETEs have both pro-inflammatory and anti-inflammatory effects, which underscores the ongoing interest in their involvement in the pathogenesis of asthma. At the same time, research results are scarce. Based on an analysis of the literature, the pathways of metabolic transformation of 5-HETE, 12-HETE, and 15-HETE with the participation of cyclooxygenases, lipoxygenases, and cytochrome P-450, as well as their role in asthma pathogenesis, were discussed. The PubMed database was searched for information covering the last five years using selected inclusion criteria. Information queries included the following set of keywords: "bronchial asthma, hydroxyeicosatetraenoic acids, 5-HETE, 12-HETE, 15-HETE." Literature data indicate that the role of HETEs in human physiology and pathology, including the modulation of inflammation in asthma, requires comprehensive study to selectively modulate the enzymatic pathways of arachidonic acid metabolism leading to the production of these mediators.

Abstract C042: Identification of a non-canonical pathway used by CAF to deliver gamma-aminobutyric acid in pancreatic cancer

Abstract Cancer-associated fibroblasts (CAFs) are cells responsible for deposition and remodeling of the extracellular matrix, and modification of the stromal microenvironment, which facilitates tumor growth. Moreover, CAFs are extremely immunosuppressive because they produce large amounts of inhibitory cytokines, growth factors and metabolites. Thus, understanding how CAFs impart severe immunosuppression in the tumor microenvironment is critical to make PDAC amenable to immunotherapies. The link between metabolism and immunosuppression in tumors has become clearer in recent years, and we postulate that one such metabolite, gamma-aminobutyric acid (GABA), a key inhibitory neurotransmitter, can act as a major immunosuppressive metabolite in PDAC. Our preliminary data shows that CAFs produce high levels of glutamate (Glu) and that metabolites derived from glutamate, such as GABA, are immunosuppressive to NK cells. Moreover, we found that CAFs could produce GABA, de novo, as determined by heavy isotope tracing. Thus, our goal is to uncover the mechanisms used by CAFs to produce GABA, and to evaluate the immunosuppressive mechanisms behind CAF- derived GABA. GABA production was measured in the conditioned media of CAFs grown in 3D culture, where it was observed that inhibition of glutaminase (GLS) and glutamine synthetase (GS) enzymes was not able to decrease the GABA levels. In addition, CAFs did not express glutamate decarboxylase (GAD), the canonical enzyme responsible for the conversion of Glu to GABA, which led us to explore the expression of a non-canonical GABA synthesis pathways in CAFs. Intriguingly, we found that CAFs derived from patient tumors expressed the enzymes of non-canonical pathway (ODC1, DAO, ALDH1A1 and ALDH9A1), and to a greater degree when compared to normal fibroblasts isolated from donor pancreata (Gift of Life Program). CRISPRi mediated knockdown (KD) of aldehyde dehydrogenase 1 (ALDH1a1) in CAFs decreased GABA production compared to control CAFs. On the other hand, CAFs knocked down for diamine oxidase (DAO), showed increased GABA production, suggesting a compensatory mechanism for GABA production upstream of ALDH1a1. Overall, our preliminary data demonstrate that CAFs produce GABA de novo, via a putative alternative GABA synthesis pathway. Our next steps are to identify the cytokine profile of KDs CAFs and perform functional assays utilizing our 3D co-culturing system, uncovering natural killer cell responses to tumor cells in the presence of CAFs with and without the enzymes necessary for GABA production. Translationally, we are analyzing the tumor interstitial fluid from PDAC patients to uncover metabolites/cytokines (secreted factors) that can be correlated with patient parameters (ex. overall survival) and immune cell activation and functionality. It is our hope that the insight provided by this study can lead to a novel set of prognostic or diagnostic factors to improve clinical outcomes in this devasting disease. Citation Format: Ariana Musa de Aquino, Myree Graves, Farrah Ali Ali, David A. Rangel, Langley Kyra, Julie Clark, David Kwon, Guillaume Cognet, Alex Muir, Débora Barbosa Vendramini Costa, Ralph Francescone. Identification of a non-canonical pathway used by CAF to deliver gamma-aminobutyric acid in pancreatic cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr C042.

Abstract B085: The HIF-2 transcription factor mediates resistance to ferroptosis in pancreatic adenocarcinoma

Abstract Ferroptosis is an iron-dependent form of cell death converging on lipid peroxidation, first identified by examining compounds with enhanced lethality to KRAS mutant cells. Two compounds widely used as ferroptosis inducers are erastin, which acts as an inhibitor of cystine import and thereby depletes cellular glutathione, and RSL-3, which inhibits glutathione peroxidase 4. Despite over 90% of pancreatic adenocarcinoma (PDAC) tumors harboring KRAS mutations, PDAC exhibits relative resistance to ferroptosis compared to other tumor types, and the mechanisms behind this resistance remain unclear. The pancreatic tumor environment is marked by severe hypoxia, due to poor vascularity and a dense fibrotic stroma, and so we hypothesized that hypoxia might mediate resistance to ferroptosis. Here we report that across a panel of human and murine PDAC cell lines, hypoxia induces resistance to both ferroptosis inducing agents, erastin and RSL-3. The effect of hypoxia was synergistic with exposure to pancreatic cancer tumor interstitial fluid, which induces a hypoxic-like gene expression profile even under normoxia and enhances hypoxic gene expression changes when combined with hypoxia. Our findings reveal that hypoxia-mediated resistance to ferroptosis is orchestrated by the hypoxia-inducible transcription factor HIF-2, as evidenced by its complete abolition in HIF-2 knockout cell lines, while the protective effect of hypoxia was maintained in HIF-1 knockout lines. RNA-seq analyses and chromatin immunoprecipitation studies (chIP) identified several HIF-2 target genes responsible for coordinating ferroptosis resistance mechanisms. Cysteine is a precursor for glutathione, and HIF-2 increased cystine import through upregulation of both components of the cystine-glutamate antiporter system Xc (SLC7A11 and SLC3A2) and increased cysteine biosynthesis via upregulation of transsulfuration pathway enzymes (CBS and CTH). In addition, HIF-2 upregulated Parkin, which we identify as a novel regulator of ferroptosis, thereby increasing mitophagy and decreasing reactive oxygen species. In vivo studies using human and murine PDAC xenograft models confirmed that HIF-2 knockout impaired tumor growth and increased susceptibility to the pro-ferroptotic agent sulfasalazine. Collectively, these data identify a mechanism by which PDAC evades ferroptosis and identifies a possible therapeutic strategy of combining HIF-2 inhibitors with pro-ferroptotic agents in pancreatic cancer. Citation Format: Maimon E Hubbi, Catherine Wang, Erin Hollander, Yasir Suhail, Kshitiz, Alexander Muir, Ben Z Stanger, Chi V Dang. The HIF-2 transcription factor mediates resistance to ferroptosis in pancreatic adenocarcinoma [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: Advances in Pancreatic Cancer Research; 2024 Sep 15-18; Boston, MA. Philadelphia (PA): AACR; Cancer Res 2024;84(17 Suppl_2):Abstract nr B085.

Pharmacological targeting of AMPK to restore glucose and fatty acid metabolism homeostasis attenuates transplanted kidney fibrosis

Chronic fibrosis often occurs in transplanted kidneys, leading to progressive functional decline. The underlying mechanisms may involve disruption in the metabolism of renal tubular epithelial cells. The liver kinase B1 (LKB1)-AMPK pathway is a pivotal regulatory hub for glucose and fatty acid metabolism and may play a role in transplanted kidney fibrosis, but it has not been reported. In this study we administered fenofibrate, 2-deoxyglucose, or metformin to modulate metabolism in Brown Norway rat kidney transplants and investigated pathways involved in fibrosis using various assays. We identified an impaired LKB1-AMPK pathway within epithelial cells, resulting in perturbed glucose and fatty acid metabolism, collagen secretion, extracellular matrix remodeling, and epithelial-mesenchymal transition. ACOX1, a pivotal enzyme in the fatty acid peroxisomal β-oxidation pathway, played an important role in transplanted renal fibrosis. Furthermore, several metabolism-targeting drugs, particularly metformin, emerged as potent fibrosis inhibitors. Metformin attenuated fibrosis, improved renal function, and reduced inflammation and macrophage infiltration in the transplanted kidneys. These results provide new perspectives for understanding the complex molecular basis underlying transplanted renal fibrosis and developing novel therapeutic strategies.

The antagonistic activity of Streptomyces spiroverticillatus (No. HS1) against of poplar canker pathogen Botryosphaeria dothidea

BackgroundPoplar canker caused by Botryosphaeria dothidea is one of the most severe plant disease of poplars worldwide. In our study, we aimed to investigate the modes of antagonism by fermentation broth supernatant (FBS) of Streptomyces spiroverticillatus HS1 against B. dothidea.ResultsIn vitro, the strain and FBS of S. spiroverticillatus HS1 significantly inhibited mycelial growth and biomass accumulation, and also disrupted the mycelium morphology of B. dothidea. On the 3rd day after treatment, the inhibition rates of colony growth and dry weight were 80.72% and 52.53%, respectively. In addition, FBS treatment damaged the plasma membrane of B. dothidea based on increased electrical conductivity in the culture medium, and malondialdehyde content of B. dothidea mycelia. Notably, the analysis of key enzymes in glycolysis pathway showed that the activity of hexokinase (HK), phosphofructokinase (PFK), and pyruvate kinase (PK), Ca2+Mg2+-ATPase were significantly increased after FBS treatment. But the glucose contents were significantly reduced, and pyruvate contents were significantly increased in B. dothidea after treatment with FBS.ConclusionsThe inhibitory mechanism of S. spiroverticillatus HS1 against B. dothidea was a complex process, which was associated with multiple levels of mycelial growth, cell membrane structure, material and energy metabolism. The FBS of S. spiroverticillatus HS1 could provide an alternative approach to biological control strategies against B. dothidea.

MBPathNCP: A Metabolic Pathway Prediction Model for Chemicals and Enzymes Based on Network Consistency Projection

Background: Metabolic pathway is an important biological pathway in living organisms as it produces necessary energy to maintain vital movement. Although main part of metabolic pathway has been uncovered by the great efforts in recent years, its completeness is still a problem. The undetected chemical reactions in metabolic pathway have become a hinder for better understanding on its mechanism. Prediction of metabolic pathways that a chemical or enzyme can participate in is the first step to remove this hinder. Objective: This study aimed to design an effective computational method to predict the metabolic pathways of chemicals and enzymes. Methods: A new computational model was proposed to predict the metabolic pathways of chemicals and enzymes, which was called MBPathNCP. The kernels for chemicals/enzymes and pathways were constructed using the interactions of chemicals and proteins, and the validated associations between chemicals/enzymes and pathways. The network consistency projection was applied to the kernels and association adjacency matrix to yield the association score for each pair of chemicals/ enzymes and pathways. Results: Cross-validation results on this model shown its good performance. The further tests indicated the reasonability of the entire architecture and its superiority when the negative samples were much than positive samples. Conclusion: The proposed model MBPathNCP was efficient to predict the metabolic pathways of chemicals and enzymes and can be a latent useful tool to investigate metabolic pathway system.

Could alternative pathways for carotenoid transformation affect colour production efficiency? A correlative study in wild common crossbills (Loxia curvirostra)

In many vertebrates, dietary yellow carotenoids are enzymatically transformed into 4C-ketocarotenoid pigments, leading to conspicuous red colourations. These colourations may evolve as signals of individual quality under sexual selection. To evolve as signals, they must transmit reliable information benefiting both the receiver and the signaler. Some argue that the reliability of 4C-ketocarotenoid-based colourations is ensured by the tight link between individual quality and mitochondrial metabolism, which is supposedly involved in transforming yellow carotenoids. We studied how a range of carotenoids covary in the feathers and blood plasma of a large number (n > 140) of wild male common crossbills (Loxia curvirostra). Plumage redness was mainly due to 3-hydroxy-echinenone (3HOE). Two other, less abundant, red 4C-ketocarotenoids (astaxanthin and canthaxanthin) could have contributed to feather colour as they are redder pigments. This was demonstrated for astaxanthin but not canthaxanthin, whose feather levels were clearly uncorrelated to colouration. Moreover, moulting crossbills carried more 3HOE and astaxanthin in blood than non-moulting ones, whereas canthaxanthin did not differ. Canthaxanthin and 3HOE can be formed from echinenone, a probable product of dietary β-carotene ketolation. Echinenone could thus be ketolated or hydroxylated to produce canthaxanthin or 3HOE, respectively. In moulting birds, 3HOE blood levels positively correlated to astaxanthin, its product, but negatively to canthaxanthin levels. Redder crossbills also had lower plasma canthaxanthin values. A decrease in hydroxylation relative to ketolation could explain canthaxanthin production. We hypothesize that red colouration could indicate birds' ability to avoid inefficient deviations within the complex enzymatic pathways.

Estimating carrier rates and prevalence of porphyria-associated gene variants in the Chinese population based on genetic databases

Porphyria is a group of rare metabolic disorders caused by mutations in the genes encoding crucial enzymes in the heme biosynthetic pathway. However, the lack of comprehensive genetic analysis of porphyria patients in the Chinese population makes identifying and diagnosing carriers of the condition challenging. Using the ChinaMAP database, we determined the frequencies of P/LP porphyria-associated gene variants according to the ACMG guidelines. We also calculated the carrier rates and prevalence of each type of porphyria in the Chinese population under Hardy–Weinberg equilibrium. Compared with the variants in the gnomAD database, the genetic spectrum of porphyria-related P/LP variants in the Chinese population is distinct. In the ChinaMAP database, we identified 23 variants. We estimated the carrier rates for autosomal dominant porphyrias (AIP, HCP, VP, PCT) in the Chinese population to be 1/1059, 1/1513, 1/10588, and 1/1765, respectively. For autosomal recessive porphyrias (ADP, EPP, HEP, CEP), the estimated carrier rates were 1/5294, 1/2117, 1/1765, and 1/2647, respectively, with predicted prevalence rates of 8.92 × 10−9, 7.51 × 10−5, 8.02 × 10−8, and 3.57 × 10−8, respectively. Notably, 12 of the variants we identified were unique to the Chinese population. The predicted prevalence rate of EPP was the highest among the various types of porphyria in the Chinese population, while the others were moderate to low. This is the first comprehensive genetic study on porphyria in the Chinese population. Clarifying the genetic characteristics of various porphyria types among the Chinese population provides scientifically sound reference data for both research and genetic screening to identify porphyria carriers.

Analysis of oil accumulation mechanisms in plasma induced mutant Scenedesmus strains compared to original Scenedesmus strains

Scenedesmus sp. is a species of the Scenedesmus genus within the phylum Chlorophyta, commonly found as a planktonic algal species in freshwater and known for its rapid growth rate. This study employs room-temperature, atmospheric-pressure plasma mutagenesis for the breeding of Scenedesmus sp., utilizing transcriptomic analysis to investigate the biosynthesis mechanism of triglycerides. Further analysis of differentially expressed genes in transcriptome by measuring the macroscopic biological indicators of mutant and original algal strains. The findings of the study suggest that the mutant strain's photosynthesis has been enhanced, leading to improved light energy utilization and CO2 fixation, thereby providing more carbon storage and energy for biomass and lipid production. The intensification of glycolysis and the TCA (tricarboxylic acid) cycle results in a greater shift in carbon flux towards lipid accumulation. An elevated expression level of related enzymes in starch and protein degradation pathways may enhance acetyl CoA accumulation, facilitating a larger substrate supply for fatty acid production and thereby increasing lipid yield.

Integrated Metabolomics and Proteomics Analysis Provides Insights into the Formation of Volatile Compounds in Three Different Polyembryonic Mango Cultivars.

Understanding volatile compound formation is critical for enhancing the flavor quality of mangoes. Integrated untargeted metabolomics and proteomics were employed to explore volatile compound formation in three different polyembryonic mango cultivars ("Ah Ping," "Rosa," and "Rosigold"). A total of 87 volatile compounds were identified using SPME-GC-MS. Untargeted metabolomics and proteomics resulted in identification of 508 metabolites and 4481 proteins, respectively. Integrative analysis revealed that the volatile compound formation was influenced by fatty acids, amino acids, pentose, and hexose, as well as terpenoid metabolisms. Specifically, upward expression of core enzymes in lipoxygenanse pathway was responsible for the higher levels of some C6 and C9 volatile compounds in "Ah Ping." The differential expression of key enzymes in fatty acid degradation facilitates the varied contents of straight-chain volatile compounds. The upregulation of glutamate decarboxylase and branched-chain amino acid aminotransferase upstream of butanoate metabolism led to the highest levels of butyl esters in "Ah Ping." Furthermore, the different levels of volatile furan and pyran compounds might be attributed to differential expression of critical enzymes in pentose and hexose metabolism. These findings established a metabolic and proteomic map unraveling the biosynthesis of specific volatile compounds and provided insights into understanding the characteristic flavor of mango.

The role of cystathionine β-synthase in cancer

Cystathionine β-synthase (CBS) occupies a key position as the initiating and rate-limiting enzyme in the sulfur transfer pathway and plays a vital role in health and disease. CBS is responsible for regulating the metabolism of cysteine, the precursor of glutathione (GSH), an important antioxidant in the body. Additionally, CBS is one of the three enzymes that produce hydrogen sulfide (H2S) in mammals through a variety of mechanisms. The dysregulation of CBS expression in cancer cells affects H2S production through direct or indirect pathways, thereby influencing cancer growth and metastasis by inducing angiogenesis, facilitating proliferation, migration, and invasion, modulating cellular energy metabolism, promoting cell cycle progression, and inhibiting apoptosis. It is noteworthy that CBS expression exhibits complex changes in different cancer models. In this paper, we focus on the CBS synthesis and metabolism, tissue distribution, potential mechanisms influencing tumor growth, and relevant signaling pathways. We also discuss the impact of pharmacological CBS inhibitors and silencing CBS in preclinical cancer models, supporting their potential as targeted cancer therapies.

Glucose-6-phosphate dehydrogenase and its 3D structures from crystallography and electron cryo-microscopy.

Glucose-6-phosphate dehydrogenase (G6PD) is the first enzyme in the pentose phosphate pathway. It has been extensively studied by biochemical and structural techniques. 13 X-ray crystal structures and five electron cryo-microscopy structures in the PDB are focused on in this topical review. Two F420-dependent glucose-6-phosphate dehydrogenase (FGD) structures are also reported. The significant differences between human and parasite G6PDs can be exploited tofind selective drugs against infections such as malaria and leishmaniasis. Furthermore, G6PD is a prognostic marker in several cancer types and is also considered to be a tumour target. On the other hand, FGD is considered to be a target against Mycobacterium tuberculosis and possesses a high biotechnological potential in biocatalysis and bioremediation.

Pharmacophore-based approach for the identification of potent inhibitors against LpxC Enzyme from Salmonella Typhi

Antimicrobial resistance (AMR) is currently a global health concern, mostly caused by microorganisms like bacteria, viruses, parasites, and fungi that acquire resistance to antimicrobial drugs. Salmonella is responsible for a variety of diseases but mainly cause typhoid. The primary concern is the rise in resistance in both non-typhoid and typhoid strains of this species. To address this issue, it is necessary to identify novel targets and strategies for the development of new antibacterial drugs. Lipid A, a strong bacterial endotoxin that modulates the immune system in human, is a key component of the virulence factor generated during the salmonella infection. Lipid A is synthesized in case of Gram-negative bacteria by cascade of nine enzyme pathway. The second step in case of Lipid A biosynthesis, catalysed by LpxC, a Zn+ dependent metallo-amidase considered as rate limiting step. In this manuscript we have used protein-ligand interaction fingerprint (PLIF)–derived pharmacophore models to screen small molecules (natural products library from Zinc database, Asinex database, Thiophene analogues) against Salmonella typhi LpxC (StLpxC). Further top hit molecules were subjected to MD-simulation and ADMET studies. We identified three optimal compounds, s1_dl_mseq2, s1_ll_mseq2, and s2_ll_mseq8, that exhibit strong binding affinity towards the LpxC active site.

Genome-Wide Characterization and Expression Analysis of CsPALs in Cucumber (Cucumis sativus L.) Reveal Their Potential Roles in Abiotic Stress and Aphid Stress Tolerance.

Phenylalanine ammonia lyase (PAL) is a pivotal enzyme in the phenylalanine metabolic pathway in plants and has a crucial role in the plant's response to environmental stress. Although the PAL family has been widely studied in many plant species, limited is known about its particular role in cucumbers under stress. We investigated the physicochemical properties, gene structure, gene duplication events, conserved motifs, cis-acting elements, protein interaction networks, stress-related transcriptome data, and quantitatively validated key stress-related genes. The main results indicated that 15 PAL genes were grouped into four clades: I, II, and III when arranged in a phylogenetic tree of PAL genes in angiosperms. The analysis of the promoter sequence revealed the presence of multiple cis-acting elements related to hormones and stress responses in the cucumber PAL genes (CsPALs). The analysis of protein interaction networks suggested that CsPAL1 interacts with eight other members of the PAL family through CsELI5 and CsHISNA, and directly interacts with multiple proteins in the 4CL family. Further investigation into the expression patterns of CsPAL genes in different tissues and under various stress treatments (NaCl, Cu2+, Zn2+, PEG6000, aphids) demonstrated significant differential expression of CsPALs across cucumber tissues. In summary, our characterization of the CsPAL family offers valuable insights and provides important clues regarding the molecular mechanisms of CsPALs in managing abiotic and biotic stress interactions in cucumbers.

The aroma transformation of Japanese sea bass (Lateolabrax japonicas) through endogenous enzyme incubation during the lag phase of attached microorganisms

Endogenous enzymes play a crucial role in determining fish product aroma. However, the attached microorganisms can promote enzyme production, making it challenging to identify specific aromatic compounds resulting from endogenous enzymes. Thus, we investigated the aroma transformation of Japanese sea bass through enzymatic incubation by controlling attached microorganisms during the lag phase. Our results demonstrate that enzymatic incubation significantly enhances grassy and sweet notes while reducing fishy odors. These changes in aroma are associated with increased levels of 10 volatile compounds and decreased levels of 3 volatile compounds. Among them, previous studies have reported enzyme reaction pathways for octanal, 1-nonanal, vanillin, indole, linalool, geraniol, citral, and 6-methyl-5-hepten-2-one; however, the enzymatic reaction pathways for germacrene D, beta-caryophyllene, pristane, 1-tetradecene and trans-beta-ocimene remain unclear. These findings provide novel insights for further study to elucidate the impact of endogenous enzymes on fish product aromas.

Endurance exercise-induced histone methylation modification involved in skeletal muscle fiber type transition and mitochondrial biogenesis

Skeletal muscle is a highly heterogeneous tissue, and its contractile proteins are composed of different isoforms, forming various types of muscle fiber, each of which has its own metabolic characteristics. It has been demonstrated that endurance exercise induces the transition of muscle fibers from fast-twitch to slow-twitch muscle fiber type. Herein, we discover a novel epigenetic mechanism for muscle contractile property tightly coupled to its metabolic capacity during muscle fiber type transition with exercise training. Our results show that an 8-week endurance exercise induces histone methylation remodeling of PGC-1α and myosin heavy chain (MHC) isoforms in the rat gastrocnemius muscle, accompanied by increased mitochondrial biogenesis and an elevated ratio of slow-twitch to fast-twitch fibers. Furthermore, to verify the roles of reactive oxygen species (ROS) and AMPK in exercise-regulated epigenetic modifications and muscle fiber type transitions, mouse C2C12 myotubes were used. It was shown that rotenone activates ROS/AMPK pathway and histone methylation enzymes, which then promote mitochondrial biogenesis and MHC slow isoform expression. Mitoquinone (MitoQ) partially blocking rotenone-treated model confirms the role of ROS in coupling mitochondrial biogenesis with muscle fiber type. In conclusion, endurance exercise couples mitochondrial biogenesis with MHC slow isoform by remodeling histone methylation, which in turn promotes the transition of fast-twitch to slow-twitch muscle fibers. The ROS/AMPK pathway may be involved in the regulation of histone methylation enzymes by endurance exercise.

SUMOylation modulates mitochondrial dynamics in an in vitro rotenone model of Parkinson's disease

SUMOylation is a post-translational modification essential for various biological processes. SUMO proteins bind to target substrates in a three-step enzymatic pathway, which is rapidly reversible by the action of specific proteases, known as SENPs. Studies have shown that SUMOylation is dysregulated in several human disorders, including neurodegenerative diseases that are characterized by the progressive loss of neurons, mitochondrial dysfunction, deficits in autophagy, and oxidative stress. Considering the potential neuroprotective roles of SUMOylation, the aim of this study was to investigate the effects of SENP3 knockdown in H4 neuroglioma cells exposed to rotenone, an in vitro model of cytotoxicity that mimics dopaminergic loss in Parkinson's disease (PD). The current data show that SENP3 knockdown increases SUMO-2/3 conjugates, which is accompanied by reduced levels of the mitochondrial fission protein Drp1 and increased levels of the mitochondrial fusion protein OPA1. Of high interest, SENP3 knockdown prevented rotenone-induced superoxide production and cellular death. Taken together, these findings highlight the importance of SUMOylation in maintaining mitochondrial homeostasis and the neuroprotective potential of this modification in PD.

Genetic mutations in Cryptococcus neoformans pyrimidine salvage pathway enzymes contribute to reduced susceptibility against 5-fluorocytosine

Cryptococcal meningitis is a high-mortality infection. Adding 5-fluorocytosine (5-FC) to its treatment improves outcomes, but resistance to 5-FC presents a significant challenge. We conducted whole-genome sequencing on seven C. neoformans isolates with varying 5-FC susceptibility, along with proteomic and in silico analyses. Our findings indicate that mutations in genes of the pyrimidine salvage pathway are responsible for 5-FC resistance. Specifically, we identified an E64G missense mutation in the FUR1 gene, a large deletion in the FCY1 gene, and a point mutation in FCY1 leading to a truncated protein. The proteomic data indicated that these mutations resulted in the absence or reduction of crucial enzymes in resistant isolates. Genetic transformations confirmed the association between these mutations and 5-FC resistance. Resistance to 5-FC can develop during treatment and is closely tied to mutations in key metabolic enzymes. Understanding in vivo resistance development is crucial for combating resistance and enhancing patient outcomes.

Fat body glycolysis defects inhibit mTOR and promote distant muscle disorganization through TNF-α/egr and ImpL2 signaling in Drosophila larvae

The fat body in Drosophila larvae functions as a reserve tissue and participates in the regulation of organismal growth and homeostasis through its endocrine activity. To better understand its role in growth coordination, we induced fat body atrophy by knocking down several key enzymes of the glycolytic pathway in adipose cells. Our results show that impairing the last steps of glycolysis leads to a drastic drop in adipose cell size and lipid droplet content, and downregulation of the mTOR pathway and REPTOR transcriptional activity. Strikingly, fat body atrophy results in the distant disorganization of body wall muscles and the release of muscle-specific proteins in the hemolymph. Furthermore, we showed that REPTOR activity is required for fat body atrophy downstream of glycolysis inhibition, and that the effect of fat body atrophy on muscles depends on the production of TNF-α/egr and of the insulin pathway inhibitor ImpL2.