We describe methods to study aspects of amylopathies in the worm C. elegans. We show how to construct worms expressing human Aβ42 in neurons and how to test their function in behavioral assays. We further show how to obtain primary neuronal cultures that can be used for pharmacological testing.
Amylopathy is a term that describes abnormal synthesis and accumulation of amyloid beta (Aβ) in tissues with time. Aβ is a hallmark of Alzheimer’s disease (AD) and is found in Lewy body dementia, inclusion body myositis and cerebral amyloid angiopathy 1-4. Amylopathies progressively develop with time. For this reason simple organisms with short lifespans may help to elucidate molecular aspects of these conditions. Here, we describe experimental protocols to study Aβ-mediated neurodegeneration using the worm Caenorhabditis elegans. Thus, we construct transgenic worms by injecting DNA encoding human Aβ42 into the syncytial gonads of adult hermaphrodites. Transformant lines are stabilized by a mutagenesis-induced integration. Nematodes are age synchronized by collecting and seeding their eggs. The function of neurons expressing Aβ42 is tested in opportune behavioral assays (chemotaxis assays). Primary neuronal cultures obtained from embryos are used to complement behavioral data and to test the neuroprotective effects of anti-apoptotic compounds.
Amyloid beta (Aβ) is a peptide of 36-43 amino acids that is formed after sequential cleavage of the amyloid precursor protein (APP) by β and γ secretases 1. The γ secretase processes the C-terminal end of the Aβ peptide and is responsible for its variable lengths 5. The most common forms of Aβ are Aβ40 and Aβ42, the latter being more commonly associated to pathologic conditions such as AD 5. At high concentrations Aβ form β-sheets that aggregate to form amyloid fibrils 6. Fibrils deposits are the main component of senile plaques surrounding neurons. Both plaques and diffusible, non-plaque Aβ oligomers, are thought to constitute the underlying pathogenic forms of Aβ.
Laboratory study of neuronal amylopathies is complicated by the fact that these conditions progress with time. Therefore, it is important to develop genetically tractable animal models-complementary to mice-with short life span. These models can be used to elucidate specific aspects of amylopathies-typically cellular and molecular-and by virtue of their simplicity, help to capture the essence of the problem. The worm Caenorhabditis elegans falls is this category. It has a short life span, ~20 days and in addition basic cellular processes including regulation of gene expression, protein trafficking, neuronal connectivity, synaptogenesis, cell signaling, and death are similar to mammalian 7. Unique features of the worm include powerful genetics and lack of a vessel system, which enables to study neuronal damage independently of vascular damage. On the other hand, the lack of a brain limits the use of C. elegans to studying many aspects of neurodegeneration. In addition, the reproduction and identification of anatomical distributions of lesions cannot be performed in this organism. Other limitations include the difficulty to assess both differences in gene expression profiles and impairment of complex behavior and memory function. Here we describe methods to generate C. elegans models of amylopathies.
1. Construction of Transgenic Worms
2. Behavioral Assays
3. Primary Embryonic Cell Culture
With our protocols we study the effects of human Aβ42 oligomer on neuronal function 8. A fragment encoding human Aβ42 and the artificial signal peptide coding sequence of Fire vector pPD50.52 was amplified from construct PCL12 9 using primers that introduced a Sma 1 restriction endonuclease site at the ends. The fragment was then inserted into a construct containing a 2,481-bp flp-6 promoter sequence in the pPD95.75 Fire vector between the unique Sma 1 site 10. Using the transformation techniques described in protocol 1 we constructed a transgenic worm expressing Aβ42 in the ASE neurons (FDX(ses25) strain) 8. To mark positive transformants we used the Pgcy-5::GFP reporter which specifically drives GFP expression in the ASE right (ASER) neuron 11. Worms stick to the pad because the dry agarose absorbs their water. Therefore it is crucial that the animals are placed onto the injection pad and injected relatively quickly, because otherwise they will desiccate and die. The percentage of F1 progeny that carries a transmissible extrachromosomal array may vary. Typical values are in the 3-7% range. It is important that the injection mix (1.1.3) contains non-encoding DNA sharing sequence homology with the transgenic DNA (usually empty vector) because the DNAs undergo homologous recombination with each other. However, if overexpression of the transgene is a problem the injection mix should be supplemented with 50-100 ng/μl of genomic DNA digested with Sca 1. ASE neurons detect water soluble attractants such as biotin and therefore their function can be assessed in behavioral assays (chemotaxis assay, protocol 2 and Figures 1A and 1B) 12. In a typical experiment, we tested seven day old worms expressing Pgcy-5::GFP alone (DA1262 strain) or with Aβ42 (FDX(ses25)) for chemotaxis to biotin. In young worms (3-4 day old) the effects of Aβ42 expression are modest but already detectable (~ 10% decrease in chemotaxis index, see ref. 8). Representative results of this experiment are shown in Figures 1C and 1D. Most DA1262 worms were found in, or nearby, the attractant spot (Figure 1C). By contrast only a few worms expressing Aβ42 could find the attractant spot (Figure 1D). We tested 100 animals/genotype distributed in 5 test plates/genotype obtaining a chemotaxis index for biotin 0.68±0.09 and 0.12±0.04 for DA1262 and FDX(ses25), respectively. Active worms were individually picked and transferred to the center of the test plate. It is important to not only quickly, but also gently transfer the worms because otherwise they may remain inactive for several minutes and fail to track the attractant. At the end of the experiment we suggest monitor worms activity by looking at their paths. If only a few tracks are visible we usually discard the plate.
GFP fluorescence in the ASER neurons of FDX(ses25) worms disappears within the first eleven days of life (not shown). This suggests that these cells undergo apoptosis due to the presence of Aβ42. Therefore we determined whether a broad-spectrum inhibitor of apoptosis such as caspase inhibitor N-(2-Quinolyl)valyl-aspartyl-(2,6-difluorophenoxy)methyl Ketone (Q-VD-OPh) 13 could stop the loss of ASER cells. To this end we employed cultured primary ASER neurons from embryos 14 , which were prepared as described in protocol 3. Representative images of an ASER neuron in a young (4 day old) FDX(ses25) worm along with images of neurons in culture are shown in Figures 2A-C. Cultured ASER cells were short-lived (Figure 2D). As expected incubation with 0.3 μg/ml Q-VD-OPh freshly supplemented daily, completely stopped the loss of fluorescent ASER neurons. When working with primary neurons in culture it is important to maintain an opportune cell density. This parameter mainly depends on the number of worms used to extract the eggs. We measure cell density with a standard hemocytometer and take particular care to maintain cell density constant from cell culture to cell culture. For pharmacological experiments such as those described here we worked with ~200,000 cells/cm2 which was obtained by harvesting four confluent 10 cm plates. Cells were plated in 12 wells of a 24-well plate. For optimal results it is also important to dissociate the embryonic cells before seeding as they tend to form clumps. We use a syringe with a 27 gauge needle and gentry aspirate the suspension back and forth a couple of times. This is generally sufficient to dissociate most of the cells (especially in the beginning we suggest to check the suspension under a microscope).
Figure 1. Chemotaxis assay. A. Representative chemotaxis plate. Attractant (biotin) and control spots are marked with an hollow and a filled circle. B. A chemotaxis plate loaded with a 0.5-cm diameter piece of agar used to establish a gradient of biotin. The piece of agar was cut from a 10-cm plate using the top side of a glass Pasteur pipette. C. Representative distribution of worms around the attractant spot. In this example the majority of DA1262 worms were able to localize the source of attractant (biotin). D. As in C. for FDX(ses25) worms. These biotin-insensitive worms exhibited a scattered distribution around the plate and only few were found near the attractant spot.
Figure 2. Culture of C. elegans embryonic cells. A. Fluorescence microscopy image (left picture) and bright light (right picture) taken from a FDX(ses25) transgenic worm head. This worm expresses GFP in the ASER neuron driven by the gcy-5 promoter. B. Bright light image of a culture of FDX(ses25) embryonic cells. Scale bar is 5 μm. C. Fluorescence microscopy image of a cultured FDX(ses25) ASER neuron. Images were taken with an Olympus BX61 microscope equipped with a digital camera. D. Representative experiment testing the viability of cultured, age-synchronized, ASER neurons. Cells were obtained from DA1262 embryos (hollow circles) or FDX(ses25) embryos maintained in the absence/presence of 300 ng/ml Q-VD-Oph (hollow and filled squares, respectively). The disappearance of GFP fluorescence was used as a measure of a neuron’s viability. The experiment started with ~300 fluorescent ASER neurons. Viability was calculated as 100*(number of fluorescent cells at day X divided by number of fluorescent cells at day 1). Click here to view larger figure.
Here we describe a combined approach, to study cellular and molecular aspects of amylopathies using C. elegans. The advantages of this approach include: 1) low cost. C.elegans is maintained in normal Petri dish seeded with bacteria, at room temperature. 2) Powerful genetics. Transgenic animals can be obtained in few months and a wide array of promoter sequences is available to drive expression of the desired gene in specific neurons. 3) Simple, well-characterized, nervous system. C. elegans possesses a remarkably simple nervous system (302 neurons). This simplicity has afforded extensive characterization of the worm’s nervous system including cell lineage, specific function/role of each neuron and its synaptic connections. The limitations of C. elegans include the small size of the cells, which hinders the application of standard biochemical techniques such as immunohistochemistry and a thick skin (cuticle) which insulates neurons form the external environment. Therefore, pharmacological approaches may be of limited efficacy in C. elegans. Cultures of primary cells represent a valid strategy to partially ameliorate this problem.
The critical steps in these experimental protocols include starting with large quantities of worms and monitoring the preparations in order to not lose eggs, embryos etc. It is also crucial to learn how to handle the animals during injection. Keeping worms in the agarose pad too long, punching them with a large pipette or injecting too much DNA mix can irreversibly damage them. Transformation efficiency, reproducibility and transgene expression may vary. Efficiency is related to the purity of the injection mix and its composition (presence of non-coding DNA). Extrachromosomal arrays vary from animal to animal therefore it is critical to establish at least 2-3, independent lines per transgene. On the other hand, the addition of digested genomic DNA to the mix represents a valid strategy to reduce transgenic over-expression. Chemotaxis assays are relatively trouble-free. However it is crucial to maintain consistency in the concentration gradient in order to avoid false results. Use pieces of agar of the same size-for example cut them with a Pasteur pipette-and maintain the equilibration time constant. If any, remove excess solution with a cotton swab.
In conclusion, here we provide an example of how a simple, genetically tractable organism can be exploited to investigate molecular aspects of amylopathies. The same experimental techniques could be applied to the study of other neuronal proteins and to the generation of new animal models of disease.
The authors have nothing to disclose.
We thank Dr. Shuang Liu for critical reading of the manuscript. The PCL12 construct was a gift form Dr. Christopher D. Link. This work was supported by two National Science Foundation grants (0842708 and 1026958) and an AHA grant (09GRNT2250529) to FS.
Name of Reagent | Company | Catalog Number | コメント |
1. NGM | |||
Sodium Chloride | Sigma-Aldrich | S5886 | 3 g |
Bacteriological agar | AMRESCO | J637 | 17 g |
Bacto-peptone | AMRESCO | J636 | 2.5 g |
Distilled Water | Bring to 975 ml | ||
Sterilized by autoclaving, then add the following items and mix well | |||
Magnesium sulfate | Sigma-Aldrich | M2643 | 1 ml of 1 M stock |
Calcium Chloride | Sigma-Aldrich | C5670 | 1 ml of 1 M stock |
Cholesterol | Sigma-Aldrich | C3045 | 1 ml of 5 mg/ml stock( in ethanol) |
Potassium phosphate buffer | 25 ml of 1M stock | ||
2. Potassium phosphate buffer | |||
Potassium phosphate monobasic | Sigma-Aldrich | P5655 | 108.3 g |
Potassium phosphate dibasic | Sigma-Aldrich | P3786 | 35.6 g |
Distilled Water | Bring to 1 L | ||
Sterilized by autoclaving | |||
3. M9 buffer | |||
Potassium phosphate monobasic | Sigma-Aldrich | P5655 | 3 g |
Sodium phosphate dibasic | Sigma-Aldrich | S5136 | 6 g |
Sodium Chloride | Sigma-Aldrich | S5886 | 5 g |
Magnesium sulfate | Sigma-Aldrich | M2643 | 1 ml of 1 M stock |
Distilled Water | Bring to 1 L | ||
Sterilized by autoclaving | |||
4. Egg buffer (pH 7.3, 340 mOsm) | |||
Sodium Chloride | Sigma-Aldrich | S5886 | 118 mM |
Potassium Chloride | Sigma-Aldrich | P5405 | 48 mM |
Calcium Chloride | Sigma-Aldrich | C5670 | 2 mM |
Magnesium Chloride | Sigma-Aldrich | M4880 | 2 mM |
HEPES | Fisher Scientific | BP310 | 25 mM |
Distilled Water | Bring to 1 L | ||
Sterilized by autoclaving | |||
5. CM-15 | |||
L-15 culture medium | Gibco | 11415 | 450 ml |
Fetal Bovine Serum | Gibco | 10437-028 | 50 ml |
Penicillin | Gibco | 15140 | 50 units/ml |
Streptomycin | Gibco | 15140 | 50 g/ml |
Adjust to 340 mOsm with sucrose then sterile filter into autoclaved bottles and store at 4 °C | |||
6. Other Reagents | |||
Halocarbon 700 oil | Halocarbon Products | 9002-83-9 | |
5 μm Acrodisc Syringe Filter | PALL Co. | 4199 | |
Chitinase | Sigma-Aldrich | C6137-5UN | |
Lectin (peanut) | Sigma-Aldrich | L0881-10MG | |
Sodium hydroxide | Fisher Scientific | S320 | |
Lysine | Sigma-Aldrich | L5501 | |
Biotin | Sigma-Aldrich | B4639 | |
Sodium hypochlorite solution | Sigma-Aldrich | 425044 | |
Sodium azide | Sigma-Aldrich | 71289 | |
Sucrose | Sigma-Aldrich | S0389 |