Sir-2.1 modulates 'calorie-restriction-mediated' prevention of neurodegeneration in Caenorhabditis elegans: implications for Parkinson's disease

The phenomenon of aging is known to modulate many disease conditions including neurodegenerative ailments like Parkinson’s disease (PD) which is characterized by selective loss of dopaminergic neurons. Recent studies have reported on such effects, as calorie restriction, in modulating aging in living systems. We reason that PD, being an age-associated neurodegenerative disease might be modulated by interventions like calorie restriction. In the present study we employed the transgenic Caenorhabditis elegans model (P_dat-1::GFP) expressing green fluorescence protein (GFP) specifically in eight dopaminergic (DA) neurons. Selective degeneration of dopaminergic neurons was induced by treatment of worms with 6-hydroxy dopamine (6-OHDA), a selective catecholaminergic neurotoxin, followed by studies on effect of calorie restriction on the neurodegeneration. Employing confocal microscopy of the dopaminergic neurons and HPLC analysis of dopamine levels in the nematodes, we found that calorie restriction has a preventive effect on dopaminergic neurodegeneration in the worm model. We further studied the role of sirtuin, sir-2.1, in modulating such an effect. Studies employing RNAi induced gene silencing of nematode sir-2.1, revealed that presence of Sir-2.1 is necessary for achieving the protective effect of calorie restriction on dopaminergic neurodegeneration.Our studies provide evidence that calorie restriction affords, an sir-2.1 mediated, protection against the dopaminergic neurodegeneration, that might have implications for neurodegenerative Parkinson’s disease.     

UNC-10在致密核心囊泡分泌过程中的作用

Rim是囊泡分泌活性区中的重要组成蛋白,它与细胞分泌和突触可塑性相关．在秀丽隐感线虫中只存在一种编码Rim的基因即unc-10．我们的研究发现,在线虫中Rim的基因突变unc-10(md1117)会导致致密核心囊泡的分泌缺陷．在活体中,unc-10突变虫系的神经多肽分泌显著下降．此外,在主要分泌致密核心囊泡的ALA神经元内,钙光解释放促发的快相分泌也比野生型减少．运用全内反射荧光显微成像技术,我们观察在unc-10缺失的情况下ALA 神经元中致密核心囊泡的锚定过程,结果显示在细胞膜附近停留的囊泡数目减少,表明囊泡锚定受到阻碍．上述试验结果表明,UNC-10能够影响致密核心囊泡的分泌过程,其机制可能是影响了囊泡的锚定过程．     

Nitrosative stress-induced Parkinsonian Lewy-like aggregates prevented through polyphenolic phytochemical analog intervention

Nitrosative stress has recently been demonstrated as a causal in a select sporadic variant of Parkinson’s (PD) and Alzheimer’s (AD) diseases. Specifically, elevated levels of NO disrupt the redox activity of protein-disulfide isomerase, a key endoplasmic reticulum-resident chaperone by S-nitroso modification of its redox-active cysteines. This leads to accumulation of misfolded AD- and PD-specific protein debris. We have recently demonstrated in vitro that polyphenolic phytochemicals, curcumin and masoprocol, can rescue S-nitroso-PDI formation by scavenging NOx. In this study, using dopaminergic SHSY-5Y cells, we have monitored the aggregation of green-fluorescent protein (GFP)-tagged synphilin-1 (a known constituent of PD Lewy neurites) as a function of rotenone-induced nitrosative stress. Importantly, we demonstrate a marked decrease in synphilin-1 aggregation when the cell line is previously incubated with 3,5-bis(2-flurobenzylidene) piperidin-4-one (EF-24), a curcumin analogue, prior to rotenone insult. Furthermore, our data also reveal that rotenone attenuates PDI expression in the same cell line, a phenomenon that can be mitigated through EF-24 intervention. Together, these results suggest that EF-24 can exert neuroprotective effects by ameliorating nitrosative stress-linked damage to PDI and the associated onset of PD and AD. Essentially, EF-24 can serve as a scaffold for the design and development of PD and AD specific prophylactics.     

Molecular Characterization of a Soybean Cyst Nematode (Heterodera glycines) Homolog of unc-87

In Caenorhabditis elegans the unc-87 gene encodes a protein that binds to actin at the I band and is important in nematodes for maintenance of the body-wall muscle. Caenorhabditis elegans mutant phenotypes of unc-87 exhibit severe paralysis in larvae and limp paralysis in the adult. We cloned and characterized a full-length cDNA representing a Heterodera glycines homolog of the unc-87 gene from C. elegans that encodes a protein that contains a region of seven repeats similar to CLIK-23 from C-elegans and has 81% amino acid identity with that of C. elegans unc-87 variant A. In the EST database clones labeled "unc-87'''' encode mainly the 3'' portion of unc-87, while clones labeled "calponin homolog OV9M'''' contain mainly DNA sequence representing the 5'' and middle transcribed regions of unc-87. A 1770 nucleotide cDNA encoding H. glycines unc-87 was cloned and encodes a predicted UNC-87 protein product of 375 amino acids. The expression of unc-87 was determined using RT-PCR and, in comparison to its expression in eggs, unc-87 was expressed 6-fold higher in J2 juveniles and 20-fold and 13-fold (P = 0.05) higher in nematodes 15 and 30 days after inoculation, respectively. In situ hybridization patterns confirmed the expression patterns observed with RT-PCR.     

Dopamine differentially induces aggregation of A53T mutant and wild type alpha-synuclein: insights into the protein chemistry of Parkinson's disease

Aggregation of α-synuclein is known to be a causal factor in the genesis of Parkinson’s disease and Dementia with Lewy bodies. Duplication and/or triplication and mutation of the α-synuclein gene are associated with sporadic and familial Parkinson’s disease. Synucleinopathies appear to primarily affect dopaminergic neurons. The present studies investigate the role of dopamine in α-synuclein aggregation through NMR. Dopamine causes aggregation of both wild type and A53T mutant α-synuclein in a temperature-dependent manner, but the mutant A53T shows a greater propensity to aggregate in the presence of dopamine only at 37 °C. A single point mutation in the α-synuclein A53T mutant gene results in a structural change in the protein and drastically increases its propensity to aggregate in the presence of dopamine. The present data indicate that mutation in the α-synuclein gene may predispose the protein to dopamine-induced aggregation, thereby contributing to disease pathogenesis.     

Protective and toxic roles of dopamine in Parkinson's disease

The molecular mechanisms causing the loss of dopaminergic neurons containing neuromelanin in the substantia nigra and responsible for motor symptoms of Parkinson's disease are still unknown. The discovery of genes associated with Parkinson's disease (such as alpha synuclein (SNCA), E3 ubiquitin protein ligase (parkin), DJ‐1 (PARK7), ubiquitin carboxyl‐terminal hydrolase isozyme L1 (UCHL‐1), serine/threonine‐protein kinase (PINK‐1), leucine‐rich repeat kinase 2 (LRRK2), cation‐transporting ATPase 13A1 (ATP13A), etc.) contributed enormously to basic research towards understanding the role of these proteins in the sporadic form of the disease. However, it is generally accepted by the scientific community that mitochondria dysfunction, alpha synuclein aggregation, dysfunction of protein degradation, oxidative stress and neuroinflammation are involved in neurodegeneration. Dopamine oxidation seems to be a complex pathway in which dopamine o‐quinone, aminochrome and 5,6‐indolequinone are formed. However, both dopamine o‐quinone and 5,6‐indolequinone are so unstable that is difficult to study and separate their roles in the degenerative process occurring in Parkinson's disease. Dopamine oxidation to dopamine o‐quinone, aminochrome and 5,6‐indolequinone seems to play an important role in the neurodegenerative processes of Parkinson's disease as aminochrome induces: (i) mitochondria dysfunction, (ii) formation and stabilization of neurotoxic protofibrils of alpha synuclein, (iii) protein degradation dysfunction of both proteasomal and lysosomal systems and (iv) oxidative stress. The neurotoxic effects of aminochrome in dopaminergic neurons can be inhibited by: (i) preventing dopamine oxidation of the transporter that takes up dopamine into monoaminergic vesicles with low pH and dopamine oxidative deamination catalyzed by monoamino oxidase (ii) dopamine o‐quinone, aminochrome and 5,6‐indolequinone polymerization to neuromelanin and (iii) two‐electron reduction of aminochrome catalyzed by DT‐diaphorase. Furthermore, dopamine conversion to NM seems to have a dual role, protective and toxic, depending mostly on the cellular context.

     

Caenorhabditis elegans neuron degeneration and mitochondrial suppression caused by selected environmental chemicals

Mitochondrial alterations have been documented for many years in the brains of Parkinson’s disease (PD), a disorder that is characterized by the selective loss of dopamine neurons. Recent studies have demonstrated that Parkinson’s disease-associated proteins are either present in mitochondria or translocated into mitochondria in response to stress, further reinforcing the importance of the mitochondrial function in the pathogenesis of Parkinson’s disease. Exposure to environmental chemicals such as pesticides and heavy metals has been suggested as risk factors in the development of Parkinson’s disease. It has been reported that a number of environmental agents including tobacco smoke and perfluorinated compounds, pesticides, as well as metals (Mn²⁺ and Pb²⁺) modulate mitochondrial function. However the exact mechanism of mitochondrial alteration has not been defined in the context of the development and progression of Parkinson’s disease. The complexity of the mammalian system has made it difficult to dissect the molecular components involved in the pathogenesis of Parkinson’s disease. In the present study we used the nematode Caenorhabditis elegans (C. elegans) model of neuron degeneration and investigated the effect of environmental chemicals on mitochondrial biogenesis and mitochondrial gene regulation. Chronic exposure to low concentration (2 or 4 μM) of pesticide rotenone, resulted in significant loss of dopamine neuron in C. elegans, a classic feature of Parkinson’s disease. We then determined if the rotenone-induced neuron degeneration is accompanied by a change in mitochondria biogenesis. Analysis of mitochondrial genomic replication by quantitative PCR showed a dramatic decrease in mitochondrial DNA (mtDNA) copies of rotenone-treated C. elegans compared to control. This decreased mitochondrial biogenesis occurred prior to the development of loss of dopamine neurons, and was persistent. The inhibition of mtDNA replication was also found in C. elegans exposed to another neuron toxicant Mn²⁺ at the concentration 50 or 100 mM. We further examined the mitochondrial gene expression and found significant lower level of mitochondrial complex IV subunits COI and COII in C. elegans exposed to rotenone. These results demonstrate that environmental chemicals cause persistent suppression of mitochondrial biogenesis and mitochondrial gene expression, and suggest a critical role of modifying mitochondrial biogenesis in toxicants-induced neuron degeneration in C. elegans model.     

Genetic and fine structure analysis of unc-26(IV) and adjacent regions in Caenorhabditis elegans

Summary The genetic organization of unc-26(IV) and adjacent regions was studied in Caenorhabditis elegans. We constructed a fine structure genetic map of unc-26(IV), a gene that affects locomotion and pharyngeal muscle movement but not muscle structure. Eleven alleles were positioned relative to each other recombinationally and were classified according to phenotypic severity. The unc-26 gene spans at least 0.026 map units, which is exceptionally large for a C. elegans gene. All but one allele, e205, are amorphic alleles. Interestingly, e205 is hypomorphic but also suppressible by the amber suppressor sup-7. Nineteen lethal mutations in the unc-26 region were isolated and characterized. The unc-26 region is subdivided into four zones by five deficiency breakpoints. These mutations fall into 15 complementation groups. The stages of development affected by these mutations were determined.     

Retrofitting ampicillin resistant vectors by recombination for use in generating C. elegans transgenic animals by bombardment

Caenorhabditis elegans is an important model organism for modern biologic research. An essential aspect of C. elegans research is the production of transgenic animals for study. These are often generated via microinjection, but biolistic bombardment has become increasingly popular. However, many of the plasmids previously generated for use in microinjection are not readily used for bombardment due to the lack of a convenient marker. The unc-119 gene is often used as a marker since unc-119 rescue can be observed at low magnification, allowing rescued animals to be easily distinguished from the larger number of non-rescued animals. Here we report the use of homologous recombination in Escherichia coli as a method to insert a cassette containing the unc-119 gene into commonly used plasmids at the site of the ampicillin resistance gene which is simpler than other methods like subcloning. These cassettes are flanked by regions homologous to the 5′ and 3′ ends of the ampicillin resistance gene and contain either the unc-119 gene and the kanamycin resistance gene or a unc-119:mCherry fusion gene and the kanamycin resistance gene. The resulting plasmids may be used for biolistic bombardment to yield animals that display unc-119 rescue, and also express the recipient plasmid transgene.     

Dopamine complexes of iron in the etiology and pathogenesis of Parkinson's disease

Parkinson’s disease (PD) is the second most common neurodegenerative disease after Alzheimers. The main pathological hallmark of Parkinson’s is the deterioration and death of neurons that produce the neurotransmitter dopamine. Much of the neuronal damage takes place in the substantia nigra, a small region of the midbrain that contains the cell bodies of neurons that produce dopamine. The deterioration and death of dopaminergic neurons are directly associated with misfolding and aggregation of proteins, principally α-synuclein, that are natively unfolded. Present also in the substantia nigra is an unusually high concentration of vestigial iron. Protein misfolding in non-genetic (sporadic) cases of PD has been associated with reactive oxygen species formed as products of O₂ reduction by the combination of dopamine and iron. Combinations of Fe³⁺, dopamine hydrochloride (DA^H+Cl), and various ancillary ligands have been studied as a function of pH in aqueous solution to determine the optimum pH for complex formation. With ancillary ligands (L₄) derived from nitrilotriacetic acid and ethylenediamine diacetic acid spectral changes are consistent with the formation of L₄Fe(DA^H+) species that reach a maximum concentration at pH 7.2. With edta as the ancillary ligand, spectral features at pH 7 resemble those of Fe³⁺-catecholate complexes that contain catecholate ligands bonded through a single oxygen. This demonstrates the ability of the dopamine catechol functionality to penetrate the coordination sphere of even exceptionally stable iron chelates.     

The hexapeptide PGVTAV suppresses neurotoxicity of human α-synuclein aggregates

In Parkinson’s disease patients, α-synuclein is the major component of the intracellular protein aggregates found in dopaminergic neurons. Previously, short synthetic α-synuclein-derived peptides have been shown to not only prevent α-synuclein fibrillation but also dissolve preformed α-synuclein aggregates in vitro. The hexapeptide PGVTAV was the shortest peptide that retained the ability to block α-synuclein fibrillation. For preventative or therapeutic effectiveness, a treatment must suppress the neurotoxicity of α-synuclein aggregates and remain stable in plasma. The present study shows that specific peptides can protect neuronal cells from α-synuclein aggregation-induced cell death. The β-sheet-breaking hexapeptide PGVTAV remained intact in human plasma for longer than one day, suggesting that it may be a candidate for the development of therapeutics to treat Parkinson’s disease.     

A biphasic dopaminergic modulation of the high voltage-activated Ba2+ current of identified snail neurons

We have investigated the intracellular mechanisms by which dopamine induced a biphasic modulation of the Ba²⁺ current amplitude through the high voltage-activated Ca²⁺ channel (HVA-I_Ba) in identifiedHelix aspersa neurons. We used the two electrode voltage clamp technique on a group of identified neurons of the right parietal ganglionin situ, and the whole cell patch clamp technique on these same neurons in primary culture. Brief application of dopamine induced an initial fast reduction of the HVA-I_Ba followed by a slower enhancement of HVA-I_Ba. This enhancement was not due to a shift of the current-voltage curve. Repetitive application of dopamine did not attenuate this phase of the response. During longer application, the inhibition began to sag and returned towards control levels. These results indicate that the enhancement was not due to a desensitization of the receptor or a relief from tonic G-protein mediated inhibition of the current. Manipulations of the levels of intracellular second messengers such as Ca²⁺, cGMP, cAMP, and arachidonic acid, as well as inhibition of protein kinases and phosphatases, had no effect on the dopamine induced biphasic effect on HVA-I_Ba. Pertussis toxin added to the patch pipette had a slow but simultaneous blocking effect on both phases of the dopamine action on HVA-I_Ba. Since our results show that pertussis toxin affects both phases of the dopamine action on this current, we suggest that both phases of the dopamine action on HVA-I_Ba are mediated by a pertussis toxin-sensitive G-protein. If a second messenger is implicated, it is none of the classical second messenger systems.     

Dopamine counteracts octopamine signalling in a neural circuit mediating food response in C. elegans

Animals assess food availability in their environment by sensory perception and respond to the absence of food by changing hormone and neurotransmitter signals. However, it is largely unknown how the absence of food is perceived at the level of functional neurocircuitry. In Caenorhabditis elegans, octopamine is released from the RIC neurons in the absence of food and activates the cyclic AMP response element binding protein in the cholinergic SIA neurons. In contrast, dopamine is released from dopaminergic neurons only in the presence of food. Here, we show that dopamine suppresses octopamine signalling through two D2‐like dopamine receptors and the G protein Gi/o. The D2‐like receptors work in both the octopaminergic neurons and the octopamine‐responding SIA neurons, suggesting that dopamine suppresses octopamine release as well as octopamine‐mediated downstream signalling. Our results show that C. elegans detects the absence of food by using a small neural circuit composed of three neuron types in which octopaminergic signalling is activated by the cessation of dopamine signalling.     

Dopamine signaling promotes the xenobiotic stress response and protein homeostasis

Multicellular organisms encounter environmental conditions that adversely affect protein homeostasis (proteostasis), including extreme temperatures, toxins, and pathogens. It is unclear how they use sensory signaling to detect adverse conditions and then activate stress response pathways so as to offset potential damage. Here, we show that dopaminergic mechanosensory neurons in C. elegans release the neurohormone dopamine to promote proteostasis in epithelia. Signaling through the DA receptor DOP‐1 activates the expression of xenobiotic stress response genes involved in pathogenic resistance and toxin removal, and these genes are required for the removal of unstable proteins in epithelia. Exposure to a bacterial pathogen (Pseudomonas aeruginosa) results in elevated removal of unstable proteins in epithelia, and this enhancement requires DA signaling. In the absence of DA signaling, nematodes show increased sensitivity to pathogenic bacteria and heat‐shock stress. Our results suggest that dopaminergic sensory neurons, in addition to slowing down locomotion upon sensing a potential bacterial feeding source, also signal to frontline epithelia to activate the xenobiotic stress response so as to maintain proteostasis and prepare for possible infection.     

模拟微重力下秀丽隐杆线虫的力学感知和肌萎缩的发生机制——太空飞行线虫试验地面平行对照研究部分

目前,微重力导致肌萎缩的分子机制尚不清楚,重力感知是该事件发生的关键环节．为了回答这一问题,在此之前首先实施了太空线虫试验,这部分结果已经在本刊报道过．而本次研究主要是在地面上建立了模拟微重力环境,观察处理后秀丽隐杆线虫（C.elegans）体壁肌细胞结构和功能的变化,一方面用于验证太空试验,同时比较两种处理结果的异同,以便于评价地面模拟微重力的有效性．经过14天19．5h旋转模拟微重力处理后,对线虫生存率和运动能力进行了观察,并检测了几个重要的肌相关基因表达和蛋白质水平．模拟微重力下线虫生存率没有明显变化,但运动频率显著下降,爬行轨迹也发生了轻微改变,运动幅度降低,提示线虫运动功能出现障碍．从形态学上观察发现：肌球蛋白A（myosin A）免疫荧光染色显示模拟微重力组肌纤维面积缩小,而肌细胞致密体（dense-body）染色可见荧光亮度下降．这些结果直接提示模拟微重力使线虫出现了肌萎缩．随后Western blotting试验结果揭示,模拟微重力组线虫体壁肌的主要结构蛋白——myosin A含量减少,进一步确证了微重力性肌萎缩发生．在基因水平,旋转后抗肌萎缩蛋白基因（dys-1）表达明显上升,而hlh-1,unc-54,myo-3和egl-19的mRNA水平均下调,提示dys-1在骨骼肌感知和传导力学信息方面有重要作用,而hlh-1,unc-54,myo-3和egl-19则分别从结构和功能两个途径促进了微重力性肌萎缩的发生和发展．本次试验所得到的结果同太空飞行试验结果十分相似,一方面强化了太空试验结论,另一方面说明在地面上模拟微重力对生物体进行研究是有效可行的,将有助于提高太空试验的质量．     

Genetic analysis of ryanodine receptor function in<Emphasis Type="Italic"> Caenorhabditis elegans</Emphasis> based on<Emphasis Type="Italic"> unc-68</Emphasis> revertants

The Caenorhabditis elegans ryanodine receptor is encoded by the unc-68 gene, and functions as a Ca²⁺-induced Ca²⁺ release channel during muscle contraction. To investigate the factors that suppress calcium release and identify molecules that interact with the ryanodine receptor, we isolated revertants from two unc-68 mutants. Three of the revertants obtained from the null allele unc-68(e540), which displayed normal motility, had intragenic mutations that resulted in failure to splice out intron 21. The other two, kh53 and kh55, had amino acid insertions in the third of the four RyR domains. The brood size and the egg laying rate remain abnormal in these revertants. This suggests the third RyR domain may be required for egg laying and embryogenesis, although we can not determine a molecular mechanism. Five ketamine sensitive revertants recovered from the missense mutant unc-68(kh30) showed altered responses to caffeine, ryanodine, levamisole and ouabain relative to those of the unc-68(kh30) animals. These may carry second-site suppressor mutations, which may define genes for proteins that regulate the Ca²⁺ concentration in body-wall muscle. One of these mutants, kh52 , shows lower motility and higher sensitivity to drugs, and this mutation was mapped to chromosome X. These observations provide a basis for the study of ryanodine receptor functions in embryogenesis and in calcium-mediated regulation of muscle contraction in C. elegans. This is the first study to show that the conserved RyR domain of the receptor acts in egg laying and embryogenesis.Communicated by C. P. Hollenberg     

Characterization of the Caenorhabditis elegans UDP-galactopyranose mutase homolog glf-1 reveals an essential role for galactofuranose metabolism in nematode surface coat synthesis

Galactofuranose (Gal_f), the furanoic form of d-galactose produced by UDP-galactopyranose mutases (UGMs), is present in surface glycans of some prokaryotes and lower eukaryotes. Absence of the Gal_f biosynthetic pathway in vertebrates and its importance in several pathogens make UGMs attractive drug targets. Since the existence of Gal_f in nematodes has not been established, we investigated the role of the Caenorhabditis elegans UGM homolog glf-1 in worm development. glf-1 mutants display significant late embryonic and larval lethality, and other phenotypes indicative of defective surface coat synthesis, the glycan-rich outermost layer of the nematode cuticle. The glf homolog from the protozoan Leishmania major partially complements C. elegans glf-1. glf-1 mutants rescued by L. major glf, which behave as glf-1 hypomorphs, display resistance to infection by Microbacterium nematophilum, a pathogen of rhabditid nematodes thought to bind to surface coat glycans. To confirm the presence of Gal_f in C. elegans, we analyzed C. elegans nucleotide sugar pools using online electrospray ionization–mass spectrometry (ESI-MS). UDP-Gal_f was detected in wild-type animals while absent in glf-1 deletion mutants. Our data indicate that Gal_f likely has a pivotal role in maintenance of surface integrity in nematodes, supporting investigation of UGM as a drug target in parasitic species.