Yeast Vps13 promotes mitochondrial function and is localized at membrane contact sites

The Vps13 protein family is highly conserved in eukaryotic cells. Mutations in human VPS13 genes result in a variety of diseases, such as chorea acanthocytosis (ChAc), but the cellular functions of Vps13 proteins are not well defined. In yeast, there is a single VPS13 orthologue, which is required for at least two different processes: protein sorting to the vacuole and sporulation. This study demonstrates that VPS13 is also important for mitochondrial integrity. In addition to preventing transfer of DNA from the mitochondrion to the nucleus, VPS13 suppresses mitophagy and functions in parallel with the endoplasmic reticulum–mitochondrion encounter structure (ERMES). In different growth conditions, Vps13 localizes to endosome–mitochondrion contacts and to the nuclear–vacuole junctions, indicating that Vps13 may function at membrane contact sites. The ability of VPS13 to compensate for the absence of ERMES correlates with its intracellular distribution. We propose that Vps13 is present at multiple membrane contact sites and that separation-of-function mutants are due to loss of Vps13 at specific junctions. Introduction of VPS13A mutations identified in ChAc patients at cognate sites in yeast VPS13 are specifically defective in compensating for the lack of ERMES, suggesting that mitochondrial dysfunction might be the basis for ChAc.     

Regulation of early endosomes across eukaryotes: Evolution and functional homology of Vps9 proteins

Endocytosis is a crucial process in eukaryotic cells. The GTPases Rab 5, 21 and 22 that mediate endocytosis are ancient eukaryotic features and all available evidence suggests retained conserved function. In animals and fungi, these GTPases are regulated in part by proteins possessing Vps9 domains. However, the diversity, evolution and functions of Vps9 proteins beyond animals or fungi are poorly explored. Here we report a comprehensive analysis of the Vps9 family of GTPase regulators, combining molecular evolutionary data with functional characterization in the non‐opisthokont model organism Trypanosoma brucei. At least 3 subfamilies, Alsin, Varp and Rabex5 + GAPVD1, are found across eukaryotes, suggesting that all are ancient features of regulation of endocytic Rab protein function. There are examples of lineage‐specific Vps9 subfamily member expansions and novel domain combinations, suggesting diversity in precise regulatory mechanisms between individual lineages. Characterization of the Rabex5 + GAPVD1 and Alsin orthologues in T. brucei demonstrates that both proteins are involved in endocytosis, and that simultaneous knockdown prevents membrane recruitment of Rab5 and Rab21, indicating conservation of function. These data demonstrate that, for the Vps9‐domain family at least, modulation of Rab function is mediated by evolutionarily conserved protein‐protein interactions.      

Distinct complexes of yeast Snx4 family SNX‐BARs mediate retrograde trafficking of Snc1 and Atg27

The yeast SNX4 sub‐family of sorting nexin containing a Bin‐Amphiphysin‐Rvs domain (SNX‐BAR) proteins, Snx4/Atg24, Snx41 and Atg20/Snx42, are required for endocytic recycling and selective autophagy. Here, we show that Snx4 forms 2 functionally distinct heterodimers: Snx4‐Atg20 and Snx4‐Snx41. Each heterodimer coats an endosome‐derived tubule that mediates retrograde sorting of distinct cargo; the v‐SNARE, Snc1, is a cargo of the Snx4‐Atg20 pathway, and Snx4‐Snx41 mediates retrograde sorting of Atg27, an integral membrane protein implicated in selective autophagy. Live cell imaging of individual endosomes shows that Snx4 and the Vps5‐Vps17 retromer SNX‐BAR heterodimer operate concurrently on a maturing endosome. Consistent with this, the yeast dynamin family protein, Vps1, which was previously shown to promote fission of retromer‐coated tubules, promotes fission of Snx4‐Atg20 coated tubules. The results indicate that the yeast SNX‐BAR proteins coat 3 distinct types of endosome‐derived carriers that mediate endosome‐to‐Golgi retrograde trafficking.      

Mapping of Vps21 and HOPS Binding Sites in Vps8 and Effect of Binding Site Mutants on Endocytic Trafficking

Vps8 is a subunit of the CORVET tethering complex, which is involved in early-to-late endosome fusion. Here, we examine the role of Vps8 in membrane fusion at late endosomes in Saccharomyces cerevisiae. We demonstrate that Vps8 associates with membranes and that this association is independent of the class C/HOPS core complex and, contrary to a previous report, also independent of the Rab GTPase Vps21. Our data indicate that Vps8 makes multiple contacts with membranes. One of these membrane binding regions could be mapped to the N-terminal part of the protein. By two-hybrid analysis, we obtained evidence for a physical interaction between Vps8 and the Rab5 homologue Vps21. In addition, the interaction with the HOPS core complex was confirmed by immunoprecipitation experiments. By deletion analysis, the Vps21 and HOPS binding sites were mapped in Vps8. Deletions that abrogated HOPS core complex binding had a strong effect on the turnover of the endocytic cargo protein Ste6 and on vacuolar sorting of carboxypeptidase Y. In contrast, deletions that abolished Vps21 binding showed only a modest effect. This suggests that the Vps21 interaction is not essential for endosomal trafficking but may be important for some other aspect of Vps8 function.The compartments of the exocytic/endocytic membrane system are dynamic structures that continuously exchange materials by budding and fusion of transport vesicles. Despite this continuous exchange, the compartments maintain their specific identities. A basic machinery consisting of tethering factors, Rab GTPases, SNARE proteins, and Sec1/Munc18 (SM) proteins accomplishes membrane targeting and fusion. For each individual membrane fusion event, a characteristic set of proteins is used.We are interested in a particular membrane fusion step, the fusion of early endosome-derived vesicles with late endosomes. Screening for vps (vacuolar protein sorting) mutants in Saccharomyces cerevisiae identified factors involved in this fusion step (3). Mutants defective in the early-to-late endosome trafficking step belong to the class D group of vps mutants, whose hallmark is an enlarged vacuole (21). Among the class D functions, representatives of the main groups of targeting and fusion factors can be found. The Q-SNARE protein Pep12, for instance, a member of the syntaxin family, serves as a marker for late endosomal membranes (2). Together with the Q-SNAREs Vti1 and Syn8 or Tlg1, it forms two alternative t-SNARE complexes on late endosomal membranes (17). These t-SNAREs combine with the v-SNARES Snc1/Snc2 or Ykt6 to form functional trans-SNARE complexes. Pep12 functionally interacts with another class D protein, the SM protein Vps45 (4). Another component of the basic fusion machinery at late endosomes is the class D protein Vps21, a member of the Rab GTPase family and the yeast homologue of mammalian Rab5 (8, 12, 30). Rab proteins are key regulators of membrane fusion (9). They are involved in the recruitment of tethering and docking factors, and by their interplay with Rab effectors they contribute to the establishment of specific membrane domains. Another class D protein connected to Rab function is Vps9, a guanidine nucleotide exchange factor (GEF) for Vps21 (11).Additional class D proteins are involved in vesicle tethering at late endosomes. Basically, there are two kinds of tethers, proteins containing extensive coiled-coil domains and large multisubunit complexes (33). The prototype of the coiled-coil tethers is p115, with its yeast homologue Uso1, involved in tethering of vesicles to Golgi apparatus membranes (25). Another member of this class is EEA1, which is involved in tethering of vesicles to endosomes. The yeast class D protein Vps19/Pep7/Vac1 could be functionally similar to EEA1 (16). Two further class D proteins, Vps3 and Vps8, are part of the multisubunit (class C core vacuole/endosome tethering) CORVET tethering complex (20, 32). This complex shares core components with the HOPS (homotypic fusion and vacuole protein sorting) tethering complex involved in homotypic vacuolar fusion (28). This core complex, the class C Vps complex, consists of Vps11/Pep5, Vps16, Vps18/Pep3, and the SM protein Vps33 (26). Instead of Vps3 and Vps8, HOPS contains two additional subunits, Vps39/Vam6 and Vps41 (35), which appear to be functionally equivalent to Vps3 and Vps8 (20). In addition to bridging donor and acceptor membranes, tethers appear to be involved in coordinating Rab and SNARE functions. This was suggested by the finding that the equivalent CORVET/HOPS subunits Vps3 and Vps39/Vam6 both display GEF activity toward their respective Rab proteins, Vps21 and Ypt7 (20, 35). In addition, whole tethering complexes act as Rab effectors by binding to activated Rab-GTP and interact with the corresponding SNARE complexes (6, 20, 31).How exactly the tethers coordinate Rab and SNARE functions during membrane fusion is at present unclear. Here, we examine the function of the CORVET subunit Vps8 (5, 13) in membrane fusion at late endosomes in yeast. We demonstrate that Vps8 directly associates with membranes. Contrary to a previous report (13), we show that this membrane association is not dependent on Vps21. We further investigate the functional relationship between Vps8 and Vps21. We found that Vps21 physically interacts with Vps8 but that this interaction does not appear to be absolutely required for endosomal trafficking. Finally, we speculate that Vps8 could be part of a higher-order structure.     

Using HHsearch to tackle proteins of unknown function: A pilot study with PH domains

Advances in membrane cell biology are hampered by the relatively high proportion of proteins with no known function. Such proteins are largely or entirely devoid of structurally significant domain annotations. Structural bioinformaticians have developed profile‐profile tools such as HHsearch (online version called HHpred), which can detect remote homologies that are missed by tools used to annotate databases. Here we have applied HHsearch to study a single structural fold in a single model organism as proof of principle. In the entire clan of protein domains sharing the pleckstrin homology domain fold in yeast, systematic application of HHsearch accurately identified known PH‐like domains. It also predicted 16 new domains in 13 yeast proteins many of which are implicated in intracellular traffic. One of these was Vps13p, where we confirmed the functional importance of the predicted PH‐like domain. Even though such predictions require considerable work to be corroborated, they are useful first steps. HHsearch should be applied more widely, particularly across entire proteomes of model organisms, to significantly improve database annotations.      

XK is a partner for VPS13A: a molecular link between Chorea-Acanthocytosis and McLeod Syndrome

Vps13 is a highly conserved lipid transfer protein found at multiple interorganelle membrane contact sites where it mediates distinct processes. In yeast, recruitment of Vps13 to different contact sites occurs via various partner proteins. In humans, four VPS13 family members, A–D, are associated with different diseases. In particular, vps13A mutants result in the neurodegenerative disorder Chorea-Acanthocytosis (ChAc). ChAc phenotypes resemble those of McLeod Syndrome, caused by mutations in the XK gene, suggesting that XK could be a partner protein for VPS13A. XK does, in fact, exhibit hallmarks of a VPS13A partner: it forms a complex with VPS13A in human cells and, when overexpressed, relocalizes VPS13A from lipid droplets to subdomains of the endoplasmic reticulum. Introduction of two different ChAc disease-linked missense mutations into VPS13A prevents this XK-induced relocalization. These results suggest that dysregulation of a VPS13A-XK complex is the common basis for ChAc and McLeod Syndrome.     

Vps15 is required for stress induced and developmentally triggered autophagy and salivary gland protein secretion in Drosophila

Autophagy is a catabolic process used to deliver cellular material to the lysosome for degradation. The core Vps34/class III phosphatidylinositol 3-kinase (PI3K) complex, consisting of Atg6, Vps15, and Vps34, is highly conserved throughout evolution, critical for recruiting autophagy-related proteins to the preautophagosomal structure and for other vesicular trafficking processes, including vacuolar protein sorting. Atg6 and Vps34 have been well characterized, but the Vps15 kinase remains poorly characterized with most studies focusing on nutrient deprivation-induced autophagy. Here, we investigate the function of Vps15 in different cellular contexts and find that it is necessary for both stress-induced and developmentally programmed autophagy in various tissues in Drosophila melanogaster. Vps15 is required for autophagy that is induced by multiple forms of stress, including nutrient deprivation, hypoxia, and oxidative stress. Furthermore, autophagy that is triggered by physiological stimuli during development in the fat body, intestine, and salivary gland also require the function of Vps15. In addition, we show that Vps15 is necessary for efficient salivary gland protein secretion. These data illustrate the broad importance of Vps15 in multiple forms of autophagy in different animal cells, and also highlight the pleiotropic function of this kinase in multiple vesicle-trafficking pathways.Autophagy is an evolutionarily conserved process in which cytoplasmic proteins or organelles are packaged into lysosomes for degradation. This process can be initiated by a variety of stimuli, such as high levels of starvation or stress, to provide nutrients to the cells or to clear the cell of damaged organelles or protein aggregates.¹ In some circumstances, autophagy can promote an alternative form of cell death, such as in the clearance of larval tissues in Drosophila melanogaster.² As defects in autophagy have been implicated in several physiological and pathological conditions, such as cancer, neurodegenerative diseases, and aging,^3,4 it is important to obtain a complete understanding of the molecular mechanisms controlling autophagy.The induction of autophagy is regulated by the Atg1/Ulk1 complex, and this complex is regulated by mechanistic target of rapamycin (mTOR).⁵ Vesicle nucleation is controlled by the class III phosphoinositide 3-kinase (PI3K) complex that generates phosphatidylinositol 3-phosphate (PI3P).⁶ This conserved complex consists of vacuolar protein sorting 34 (Vps34; also known as Pik3c3), Atg6/Becn1 (also known as Vps30 in yeast), and the serine-threonine kinase Vps15/ird1 (p150 in mammals; also known as Pik3r4).^7,8 Localized production of PI3P by Vps34 can act to recruit proteins containing PX or FYVE domains to membrane compartments, such as the autophagosome isolation membrane.⁹ Vps34 is also required more broadly for several vesicular trafficking processes such as the sorting of hydrolytic enzymes to the yeast vacuole and mammalian lysosome, and endocytic trafficking.^{10, 11, 12} There is mounting evidence demonstrating the pleiotropic function of the PI3K/Vps34 complex, but this has not been well studied in the context of autophagy under different physiological and cell contexts in animals.Of the three core PI3K complex proteins, Vps15 remains an understudied kinase, and its function has not been rigorously investigated in multicellular organisms in vivo. Most of the focus on the role of this complex in autophagy regulation has been on nutrient deprivation-initiated autophagy. Indeed, previous studies determined Vps15 to be necessary for starvation-induced autophagy in the Drosophila larval fat body.^13,14 However, its role in hormone-regulated autophagy, a process that occurs in the intestine,¹⁵ salivary glands,¹⁶ and fat body¹⁷ of developing Drosophila, as well as its role in other stress-induced conditions have not yet been examined. In order to address the role of Vps15 in these and other processes regulated by autophagy, we utilized Vps15 knockdown as well as a previously described null mutant¹⁴ to examine its role in a multicellular organism in vivo. We found that Vps15 is required not only for stress-induced autophagy in multiple tissues, but it is also a broad regulator of developmentally programmed autophagy in Drosophila. In addition, Vps15 is necessary for efficient protein secretion, as indicated by its role in the secretion of glue proteins from the Drosophila salivary gland. Together, these results highlight the importance of Vps15 in multiple processes in vivo.     

Proteomic profiling of patient‐derived glioblastoma xenografts identifies a subset with activated EGFR: implications for drug development

The development of drugs to inhibit glioblastoma (GBM) growth requires reliable pre‐clinical models. To date, proteomic level validation of widely used patient‐derived glioblastoma xenografts (PDGX) has not been performed. In the present study, we characterized 20 PDGX models according to subtype classification based on The Cancer Genome Atlas criteria, TP53, PTEN, IDH 1/2, and TERT promoter genetic analysis, EGFR amplification status, and examined their proteomic profiles against those of their parent tumors. The 20 PDGXs belonged to three of four The Cancer Genome Atlas subtypes: eight classical, eight mesenchymal, and four proneural; none neural. Amplification of EGFR gene was observed in 9 of 20 xenografts, and of these, 3 harbored the EGFRvIII mutation. We then performed proteomic profiling of PDGX, analyzing expression/activity of several proteins including EGFR. Levels of EGFR phosphorylated at Y1068 vary considerably between PDGX samples, and this pattern was also seen in primary GBM. Partitioning of 20 PDGX into high (n = 5) and low (n = 15) groups identified a panel of proteins associated with high EGFR activity. Thus, PDGX with high EGFR activity represent an excellent pre‐clinical model to develop therapies for a subset of GBM patients whose tumors are characterized by high EGFR activity. Further, the proteins found to be associated with high EGFR activity can be monitored to assess the effectiveness of targeting EGFR.

     

Ratio of ellipticities between 192 and 208 nm (R1): An effective electronic circular dichroism parameter for characterization of the helical components of proteins and peptides

Circular dichroism (CD) spectroscopy represents an important tool for characterization of the peptide and protein secondary structures that mainly arise from the conformational disposition of the peptide backbone in solution. In 1991 Manning and Woody proposed that, in addition to the signal intensity, the ratio between and ((R₂ ) ? [θ]₂₂₂/[θ]₂₀₈), along with and ((R₁ ) ? [θ]₁₉₂/[θ]₂₀₈), may be utilized towards identifying the peptide/protein conformation (especially 3₁₀‐ and α‐helices). However, till date the use of the ratiometric ellipticity component for helical structure analysis of peptides and proteins has not been reported. We studied a series of temperature dependent CD spectra of a thermally stable, model helical peptide and its related analogs in water as a function of added 2,2,2‐trifluoroethanol (TFE) in order to explore their landscape of helicity. For the first time, we have experimentally shown here that the R₁ parameter can characterize better the individual helices, while the other parameter R₂ and the signal intensity do not always converge. We emphasize the use of the R₁ ratio of ellipticities for helical characterization because of the common origin of these two bands (exciton splitting of the amide π→ π* transition in a helical polypeptide). This approach may become worthwhile and timely with the increasing accessibility of CD synchrotron sources.     

An Arabidopsis ATPase gene involved in nematode‐induced syncytium development and abiotic stress responses

The beet cyst nematode Heterodera schachtii induces syncytia in the roots of Arabidopsis thaliana, which are its only nutrient source. One gene, At1g64110, that is strongly up‐regulated in syncytia as shown by RT‐PCR, quantitative RT‐PCR, in situ RT‐PCR and promoter::GUS lines, encodes an AAA+‐type ATPase. Expression of two related genes in syncytia, At4g28000 and At5g52882, was not detected or not different from control root segments. Using amiRNA lines and T‐DNA mutants, we show that At1g64110 is important for syncytium and nematode development. At1g64110 was also inducible by wounding, jasmonic acid, salicylic acid, heat and cold, as well as drought, sodium chloride, abscisic acid and mannitol, indicating involvement of this gene in abiotic stress responses. We confirmed this using two T‐DNA mutants that were more sensitive to abscisic acid and sodium chloride during seed germination and root growth. These mutants also developed significantly smaller roots in response to abscisic acid and sodium chloride. An in silico analysis showed that ATPase At1g64110 (and also At4g28000 and At5g52882) belong to the ‘meiotic clade’ of AAA proteins that includes proteins such as Vps4, katanin, spastin and MSP1.     

Differential effects of ethanol on regional glutamatergic and GABAergic neurotransmitter pathways in mouse brain

This study investigates the effects of ethanol on neuronal and astroglial metabolism using ¹H‐[¹³C]‐NMR spectroscopy in conjunction with infusion of [1,6‐¹³C₂]/[1‐¹³C]glucose or [2‐¹³C]acetate, respectively. A three‐compartment metabolic model was fitted to the ¹³C turnover of Glu_C3, Glu_C4, GABA_C2, GABA_C3, Asp_C3, and Gln_C4 from [1,6‐¹³C₂]glucose to determine the rates of tricarboxylic acid (TCA) and neurotransmitter cycle associated with glutamatergic and GABAergic neurons. The ratio of neurotransmitter cycle to TCA cycle fluxes for glutamatergic and GABAegic neurons was obtained from the steady‐state [2‐¹³C]acetate experiment and used as constraints during the metabolic model fitting. ¹H MRS measurement suggests that depletion of ethanol from cerebral cortex follows zero order kinetics with rate 0.18 ± 0.04 μmol/g/min. Acute exposure of ethanol reduces the level of glutamate and aspartate in cortical region. Gln_C4 labeling was found to be unchanged from a 15 min infusion of [2‐¹³C]acetate suggesting that acute ethanol exposure does not affect astroglial metabolism in naive mice. Rates of TCA and neurotransmitter cycle associated with glutamatergic and GABAergic neurons were found to be significantly reduced in cortical and subcortical regions. Acute exposure of ethanol perturbs the level of neurometabolites and decreases the excitatory and inhibitory activity differentially across the regions of brain.

     

Glutamatergic and GABAergic energy metabolism measured in the rat brain by 13C NMR spectroscopy at 14.1 T

Energy metabolism supports both inhibitory and excitatory neurotransmission processes. This study investigated the specific contribution of astrocytic metabolism to γ‐aminobutyric acid (GABA) synthesis and inhibitory GABAergic neurotransmission that remained to be ilucidated in vivo. Therefore, we measured ¹³C incorporation into brain metabolites by dynamic ¹³C nuclear magnetic resonance spectroscopy at 14.1 T in rats under α‐chloralose anaesthesia during infusion of [1,6‐¹³C]glucose. The enhanced sensitivity at 14.1 T allowed to quantify incorporation of ¹³C into the three aliphatic carbons of GABA non‐invasively. Metabolic fluxes were determined with a mathematical model of brain metabolism comprising glial, glutamatergic and GABAergic compartments. GABA synthesis rate was 0.11 ± 0.01 μmol/g/min. GABA‐glutamine cycle was 0.053 ± 0.003 μmol/g/min and accounted for 22 ± 1% of total neurotransmitter cycling between neurons and glia. Cerebral glucose oxidation was 0.47 ± 0.02 μmol/g/min, of which 35 ± 1% and 7 ± 1% was diverted to the glutamatergic and GABAergic tricarboxylic acid cycles, respectively. The remaining fraction of glucose oxidation was in glia, where 12 ± 1% of the TCA cycle flux was dedicated to oxidation of GABA. 16 ± 2% of glutamine synthesis was provided to GABAergic neurons. We conclude that substantial metabolic activity occurs in GABAergic neurons and that glial metabolism supports both glutamatergic and GABAergic neurons in the living rat brain.

     

Distinct roles of the two VPS33 proteins in the endolysosomal system in Caenorhabditis elegans

Sec1/Munc‐18 (SM) family proteins are essential regulators in intracellular transport in eukaryotic cells. The SM protein Vps33 functions as a core subunit of two tethering complexes, class C core vacuole/endosome tethering (CORVET) and homotypic fusion and vacuole protein sorting (HOPS) in the endocytic pathway in yeast. Metazoan cells possess two Vps33 proteins, VPS33A and VPS33B, but their precise roles remain unknown. Here, we present a comparative analysis of Caenorhabditis elegans null mutants for these proteins. We found that the vps‐33.1 (VPS33A) mutants exhibited severe defects in both endocytic function and endolysosomal biogenesis in scavenger cells. Furthermore, vps‐33.1 mutations caused endocytosis defects in other tissues, and the loss of maternal and zygotic VPS‐33.1 resulted in embryonic lethality. By contrast, vps‐33.2 mutants were viable but sterile, with terminally arrested spermatocytes. The spermatogenesis phenotype suggests that VPS33.2 is involved in the formation of a sperm‐specific organelle. The endocytosis defect in the vps‐33.1 mutant was not restored by the expression of VPS‐33.2, which indicates that these proteins have nonredundant functions. Together, our data suggest that VPS‐33.1 shares most of the general functions of yeast Vps33 in terms of tethering complexes in the endolysosomal system, whereas VPS‐33.2 has tissue/organelle specific functions in C. elegans.      

In vivo NMR studies of regional cerebral energetics in MPTP model of Parkinson's disease: recovery of cerebral metabolism with acute levodopa treatment

In this study, we have evaluated cerebral atrophy, neurometabolite homeostasis, and neural energetics in 1‐methyl‐4‐phenyl‐1,2,3,6‐tetrahydropyridin (MPTP) model of Parkinson's disease. In addition, the efficacy of acute l ‐DOPA treatment for the reversal of altered metabolic functions was also evaluated. Cerebral atrophy and neurochemical profile were monitored in vivo using MRI and ¹H MR Spectroscopy. Cerebral energetics was studied by ¹H‐[¹³C]‐NMR spectroscopy in conjunction with infusion of ¹³C labeled [1,6^‐13C₂]glucose or [2‐¹³C]acetate. MPTP treatment led to reduction in paw grip strength and increased level of GABA and myo‐inositol in striatum and olfactory bulb. ¹³C Labeling of glutamate‐C4 (1.93 ± 0.24 vs. 1.48 ± 0.06 μmol/g), GABA‐C2 (0.24 ± 0.04 vs. 0.18 ± 0.02 μmol/g) and glutamaine‐C4 (0.26 ± 0.04 vs. 0.20 ± 0.04 μmol/g) from [1,6‐¹³C₂]glucose was found to be decreased with MPTP exposure in striatum as well as in other brain regions. However, glutamine‐C4 labeling from [2‐¹³C]acetate was found to be increased in the striatum of the MPTP‐treated mice. Acute l ‐DOPA treatment failed to normalize the increased ventricular size and level of metabolites but recovered the paw grip strength and ¹³C labeling of amino acids from [1,6‐¹³C₂]glucose and [2‐¹³C]acetate in MPTP‐treated mice. These data indicate that brain energy metabolism is impaired in Parkinson's disease and acute l ‐DOPA therapy could temporarily recover the cerebral metabolism.

     

Chemical Composition and Biological Prospects of Essential Oils and Extracts of Aphyllocladus spartioides Growing in Northwest Argentina

Aphyllocladus spartioides Wedd . is a native and aromatic herb used in traditional medicine, however it is still poorly investigated. In this work, the volatile profile of A. spartioides growing in Hornillos‐Northwest Argentina was determined by GC/MS/FID and the phenolic compounds of hydroethanolic and decoction extracts were analyzed by HPLC‐DAD. The antibacterial potential, antioxidant activity and α‐glucosidase inhibition activity were checked by in vitro assays. The volatile profile allowed the identification of 68 compounds, being α‐pinene and cadinene the main ones. Eighteen phenolics were identified, isorhamnetin derivatives and different phenolic acid derivatives were found in higher amounts, mainly in the hydroethanolic extract. A concentration‐dependent activity was noticed against DPPH^·, , and α‐glucosidase, these activities being reported for the first time. Hydroethanolic extract was most active against DPPH^·, ^·NO and α‐glucosidase (IC₅₀ = 79, 206 and 181 μg/ml). Decoction extract proved to be better against (IC₅₀ = 20 μg/ml). Regarding the antibacterial activity, hydroethanolic extract was more active compared with decoction and essential oil. MICs of 0.3 – 0.6 mg/ml were obtained against Staphylococcus aureus, Bacillus cereus, and Micrococcus luteus. Results suggest that the extracts of A. spartioides from Northwest Argentina may be interesting to use as a source of natural antioxidants/antimicrobials for pharmaceutical incorporations or food supplementation.