Lifespan regulation under axenic dietary restriction: a close look at the usual suspects.

In Caenorhabditis elegans, there are several ways to impose dietary restriction (DR) all of which extend lifespan to a different degree. Until recently, the molecular mechanisms underlying the DR-mediated lifespan extension were completely unknown but extensive efforts led to the identification of several key players in this process. Culture in sterile axenic medium is a method of DR (ADR), leading to an impressive doubling of lifespan. Earlier, we established that ADR-mediated longevity is independent of Ins/IGF signaling and eat-2. The only gene reported to be indispensable for the ADR lifespan effect is cbp-1 (Zhang et al., 2009) which was confirmed in this study. In an attempt to identify more genes involved in ADR-mediated longevity, we tested several candidate genes known to regulate lifespan extension in other DR regimens. We found that cup-4 is equally important as cbp-1 in ADR-mediated longevity and we identified some genes that may contribute to ADR-induced longevity, but are not required for the full lifespan effect.

Insulin-like signaling, metabolism, stress resistance and aging in Caenorhabditis elegans.

The nervous system acts as a major regulator of the life span of Caenorhabditis elegans. Temperature and chemical stimuli from the environment are integrated with internal signals from the reproductive system to specify adult longevity. An insulin-like signaling cascade acts in neurons and coordinates control of senescence of the entire organism by regulating metabolism and a stress response mechanism. Caloric restriction extends life span, possibly by activation of the stress response program.

Copper induces apoptosis in Aedes C6/36 cells.

The Aedes albopictus C6/36 cell clone is used as a model system to study the effects of heavy metals on insect cells. Here we report on the effects of Cu(2+) on these cells. Similar to Cd(2+) and Hg(2+), Cu(2+) induces hyperpolymerization of the microtubules; moreover, with Cu(2+) this is followed by cell aggregation and massive apoptosis. This process, which is cell density dependent, is maximal between 0.75 and 1 mM; this is just under the LC(50) as determined by a membrane integrity test. At higher Cu(2+) concentrations, cell death occurs by necrosis. Apoptosis was ascertained by fluorescence and electron microscopy and by agarose gel electrophoresis. At 0.75 mM, apoptosis started at 18-hr exposure time and the amount of apoptotic cells increased almost linearly until 42 hr; then a plateau was reached with 70-80% apoptotic cells. This is the first report on Cu(2+)-induced apoptosis in insect cells. Possible induction mechanisms are discussed in the light of existing literature on vertebrate cells.

Patterns of metabolic activity during aging of the wild type and longevity mutants of Caenorhabditis elegans.

At least three mechanisms determine life span in Caenorhabditis elegans. An insulin-like signaling pathway regulates dauer diapause, reproduction and longevity. Reduction-or loss-of-function mutations in this pathway can extend longevity substantially, suggesting that the wild-type alleles shorten life span. The mutations extend life span by activating components of a dauer longevity assurance program in adult life, resulting in altered metabolism and enhanced stress resistance. The Clock (Clk) genes regulate many temporal processes, including life span. Mutation in the Clk genes clk-1 and gro-1 mildly affect energy production, but repress energy consumption dramatically, thereby reducing the rate of anabolic metabolism and lengthening life span. Dietary restriction, either imposed by mutation or by the culture medium increases longevity and uncovers a third mechanism of life span determination. Dietary restriction likely elicits the longevity assurance program. There is still uncertainty as to whether these pathways converge on daf-16 to activate downstream longevity effector genes such as ctl-1 and sod-3. There is overwhelming evidence that the interplay between reactive oxygen species (ROS) and the capacity to resist oxidative stress controls the aging process and longevity. It is as yet not clear whether metabolic homeostasis collapses with age as a direct result of ROS-derived damage or is selectively repressed by longevity-determining genes. The dramatic decline of protein turnover during senescence results in the accumulation of altered enzymes and in a gradual decline of metabolic performance eventually followed by fatal failure of the system.

Apparent uncoupling of energy production and consumption in long-lived Clk mutants of Caenorhabditis elegans.

Clk mutants of Caenorhabditis elegans are characterised by an overall slow down of temporal processes and increase in life span. It was hypothesised that Clk mutations slow down the pace of many cellular functions and lower the rate of energy metabolism, possibly resulting in slower production of reactive oxygen species which in turn could result in slower ageing. We tested this hypothesis by measuring respiration rates, light production capacities (a measure of metabolic potential) and ATP levels in various strains harbouring mutant alleles of the Clk genes clk-1 and gro-1 and of three other genes that interact with the Clk genes. We found a mild reduction of oxygen consumption rates but little alteration of metabolic capacities in the single Clk mutants during the first 4-5 days of their adult lives, relative to the wild-type strain. This difference tended to fade away with increasing age, however, and aged Clk mutants eventually retained higher metabolic capacities than the wild-type control strain N2. These profiles are suggestive of physiological time being retarded, relative to chronological time in Clk mutants. Ageing clk-1 and gro-1 mutants also retained substantially elevated ATP levels relative to the N2 strain, and the simultaneous presence of mutations in daf-2 or age-1 - genes that affect longevity - boosted this effect. Thus, energy production and consumption appear to be uncoupled in these mutants. Mutation in the transcription factor daf-16 suppressed the Age and ATP phenotypes, but not the reduction of respiration rate imparted by mutation in clk-1.

Cadmium uptake and defense mechanism in insect cells.

The uptake of cadmium and the defense mechanism against this heavy metal were studied in the Aedes albopictus C6/36 cell line. The internalization of cadmium was a very quick process and exhibited saturation kinetics over the metal concentration gradient (1.37 to 131 micromol/L). Cd toxicity and influx were both shown to be temperature dependent. The uptake was not influenced by a 2, 4-dinitrophenol pretreatment but was significantly decreased by the Ca2+ antagonist verapamil. These data suggest that cadmium is readily taken up through mediated transport, not requiring metabolic energy. A considerable amount of the metal passes through the Ca2+ channels, but probably (an)other transporting molecule(s) also play(s) an important role in the uptake process. The remarkable, nonsigmoid viability pattern of Cd-treated cultures suggests that CdCl2 concentrations above 33 micromol/L induce a cellular defense system. This phenomenon went together with increased protein synthesis. We found a major induction of a group consisting of 71-, 75-, and 78-kDa proteins, probably belonging to the HSP70 family, as similar proteins were induced by heat shock. A slight induction of a 120-kDa protein also occurred. At the highest Cd concentrations 98-, 108-, and 110-kDa proteins were induced. These data suggest that heat shock proteins may play an important role in the Aedes cell protection against Cd insult.

Mechanisms of life span determination in Caenorhabditis elegans.

Molecular analysis of several gerontogenes of Caenorhabditis elegans has led to the discovery of at least two life span-controlling pathways. An insulin-like signaling cascade consisting of proteins encoded by the genes daf-2, age-1, akt-1, akt-2, daf-16 and daf-18 regulates dauer diapause, reproduction, and longevity. This pathway regulates all three processes systemically. daf-12 interacts with it, affecting dauer diapause and longevity. Life span extension mediated by this pathway probably results from the activation of an enhanced life-maintenance program, which is normally operative during dauer diapause. A different mechanism is specified by the clock genes clk-1, clk-2, clk-3 and gro-1, which regulate metabolic activity and the pace of many temporal processes including longevity. There is some controversy as to whether the life span extension observed in these mutants requires the activity of daf-16. All known gerontogenes appear to confer resistance to environmental stress, usually multiple stress factors, including oxidative stress, high temperature, and exposure to ultraviolet radiation. Caloric restriction extends longevity substantially, and may act by activating the enhanced life-maintenance program.

Cadmium pathology in an insect cell line: ultrastructural and biochemical effects.

Cadmium (Cd) pathology was studied in an insect cell line (Aedes albopictusC6/36) at the ultrastructural level. The most prominent pathological changes occurred at the level of the nucleus: chromatin clumping, indentations, filling and dilatation of the perinuclear cisternae and an increased amount of bound ribosomes were observed. In the cytoplasm, condensation and swelling of mitochondria, increase of both free and membrane-bound ribosomes, filling and dilatation of the rough endoplasmic reticulum, and increase of the lysosomal system were the most conspicuous effects. The increased content of the perinuclear and cytoplasmic cisternae was probably due to an increased protein synthesis or a disturbance of the protein export system. This picture differed clearly from the osmotically swollen electron-lucent cisternae that have been described in other pathological situations. The enhancement of the lysosomal system was paralleled by a slight but significant stimulation of the acid phosphatase activity in the sublethal Cd concentration range. In vitro experiments suggested that Cd probably acts directly on this enzyme. Abnormal medium acidification in cultures treated with low Cd levels was correlated with an increased production of lactic acid. Together with the morphological data, this suggested a Cd-induced impairment of the aerobic metabolism.

Two-parameter logistic and Weibull equations provide better fits to survival data from isogenic populations of Caenorhabditis elegans in axenic culture than does the Gompertz model.

We have fitted Gompertz, Weibull, and two- and three-parameter logistic equations to survival data obtained from 77 cohorts of Caenorhabditis elegans in axenic culture. Statistical analysis showed that the fitting ability was in the order: three-parameter logistic > two-parameter logistic = Weibull > Gompertz. Pooled data were better fit by the logistic equations, which tended to perform equally well as population size increased, suggesting that the third parameter is likely to be biologically irrelevant. Considering restraints imposed by the small population sizes used, we simply conclude that the two-parameter logistic and Weibull mortality models for axenically grown C. elegans generally provided good fits to the data, whereas the Gompertz model was inappropriate in many cases. The survival curves of several short- and long-lived mutant strains could be predicted by adjusting only the logistic curve parameter that defines mean life span. We conclude that life expectancy is genetically determined; the life span-altering mutations reported in this study define a novel mean life span, but do not appear to fundamentally alter the aging process.

Age-specific modulation of light production potential, and alkaline phosphatase and protein tyrosine kinase activities in various age mutants of Caenorhabditis elegans.

Previous work has shown that reduction-of-function mutations in the genes daf-2 and age-1 can increase adult life (Age phenotype) of Caenorhabditis elegans and that certain daf-12 alleles considerably amplify this effect in daf-2; daf-12 doubles. We have measured the light production potential (LPP) and alkaline phosphatase (ALP) and protein tyrosine kinase (PTK) activity levels as suitable biochemical markers to further investigate genetic interactions between these genes. The light production assay measures superoxide anion production by freeze-thawed worms in assay medium containing sufficient amounts of nicotineamide adenine dinucleotide, reduced form (NADH) and nicotineamide adenine dinucleotide phosphate, reduced form (NADPH) to drive the chemiluminescent reaction at maximal speed, and 5 mM cyanide to fully repress cytosolic superoxide dismutase (SOD). This assay thus provides an estimate of the maximum output of the metabolic pathways involved at the instant of freeze-fixation, and under the condition of the assay. LPP and PTK activities decreased similarly in daf-12(m20), and a control strain that had wild-type alleles of daf-12, age-1, and daf-2. The age-dependent decrease of LPP and PTK was reduced in age-1(hx542) and age-1(hx542); daf-2(e1370), and virtually absent in daf-2(e1370) and daf-2(e1370); daf-12(m20) mutant worms. ALP activity increased with age in non-Age genotypes and showed little, if any, age-dependent alteration in daf-2(e1370) and daf-2(e1370); daf-12(m20) mutant worms. Mutation in both age-1 and daf-2 caused no stronger phenotype than a single mutation as estimated by LPP, PTK, and ALP. We propose that (a) daf-2 is the major effector of metabolic activity during adult life, (b) daf-2 downregulates metabolic activity with increasing age, and (c) daf-12 stimulates oxygen consumption independently of daf-2.

Uptake of HgCl2 and MeHgCl in an insect cell line (Aedes albopictus C6/36).

We studied the uptake mechanism of mercuric chloride (Hg) and methylmercuric chloride (MeHg) in Aedes albopictus C6/36 cells. The uptake kinetics, together with the effect of temperature and a metabolic inhibitor (2, 4-dinitrophenol) on the mercury accumulation, were examined. Both amounts of internalized Hg and MeHg increased linearly with the extracellular concentration. Initially, the influx rate was high for both metal species but MeHg was found to accumulate seven times faster than Hg. At longer exposure times it leveled off for Hg, while for MeHg, the intracellular concentration decreased. Hg toxicity was not significantly influenced by elevated temperatures; in contrast there was a marked decrease of the LC50/24h value for MeHg. On the other hand, Hg accumulation was temperature dependent but MeHg was not. The different toxicity and uptake rate of both mercury compounds can be explained in terms of membrane permeability and target site. For Hg the main target seems to be the plasma membrane, while MeHg readily crosses this barrier and reacts with intracellular targets. 2, 4-Dinitrophenol had no effect on the accumulation of Hg but that of MeHg was doubled. This increased MeHg accumulation might be the result of the inhibition of an active MeHg efflux mechanism; this is in agreement with the MeHg influx kinetics. Despite these differences between Hg and MeHg, which probably result from their physicochemical properties, our experiments indicate that, for both mercury species, simple diffusion is probably the main way to entrance in Aedes cells.

Heavy-metal toxicity in an insect cell line. Effects of cadmium chloride, mercuric chloride and methylmercuric chloride on cell viability and proliferation in Aedes albopictus cells.

We evaluated the toxicity of CdCl2, HgCl2, and MeHgCl on the C6/36 cell line of Aedes albopictus. This cell line proved to be a suitable tool for studying heavy-metal toxicity in insect cells. Since data on heavy-metal toxicity in invertebrate cell cultures are almost nonexistent, our results are discussed in relation to in vivo invertebrate and in vitro vertebrate studies. Viability and proliferation were assessed by dye exclusion and DNA quantification, respectively. Viability tests were carried out with and without 5% fetal calf serum in the medium. The three metal species decreased viability to different extents (MeHgCl > HgCl2 > CdCl2), and fetal calf serum had a protective effect. In serum-deprived cultures, LD50 values were 140.20, 2.51, and 2.08 mumol/L for CdCl2, HgCl2, and MeHgCl, respectively. For cultures with fetal calf serum, LD50 values were 149.71, 12.01, and 5.47 mumol/L, respectively. The viability curve for CdCl2 under serum-free conditions suggests the induction of a cell defense system. The three metal species also inhibited cell proliferation (MeHgCl > CdCl2 > HgCl2). The IC50 values were 1.75, 18.36, and 0.96 mumol/L for CdCl2, HgCl2, and MeHgCl, respectively. In summary, low MeHgCl concentrations caused both cell death and inhibition of cell proliferation; HgCl2 primarily disrupted the plasma membrane, whereas CdCl2 primarily inhibited cell proliferation.

Effect of sublethal doses of cadmium, inorganic mercury and methylmercury on the cell morphology of an insect cell line (Aedes albopictus, C6/36).

The effect of CdCl2 (44 microM), HgCl2 (3.7 microM), and MeHgCl (2 microM) on the morphology of Aedes albopictus C6/36 cells was studied at the light microscopical level. Treatment times and metal concentrations were in the sublethal range as determined by a fluorometric dye exclusion test. The three metal species had profound effects on the cell morphology. MeHgCl treatment induced the development of a large number of short, actin-supported, tangled filopodia. Both CdCl2 and HgCl2 induced long extensions. Pretreatment with colchicine but not with cytochalasin B prevented formation of these extensions which suggests that they were supported by microtubules. This was confirmed by immunostaining for microtubules. The extensions were relatively stable towards colchicine post-treatment. To authors' knowledge, this effect has not yet been described for heavy metals. The similarity with 20-hydroxyecdysone-treated cells and the occurrence of cytoplasmic feet in insect cells is discussed.