Here we describe methods for assessing cellular response to acute mechanical stimulation. In the microscopy-based assay, we examine localization of fluorescently-labeled biosensors following brief stimulation with shear flow. We also test activation of various proteins of interest in response to acute mechanical stimulation biochemically.
Chemotaxis, or migration up a gradient of a chemoattractant, is the best understood mode of directed migration. Studies using social amoeba Dictyostelium discoideum revealed that a complex signal transduction network of parallel pathways amplifies the response to chemoattractants, and leads to biased actin polymerization and protrusion of a pseudopod in the direction of a gradient. In contrast, molecular mechanisms driving other types of directed migration, for example, due to exposure to shear flow or electric fields, are not known. Many regulators of chemotaxis exhibit localization at the leading or lagging edge of a migrating cell, as well as show transient changes in localization or activation following global stimulation with a chemoattractant. To understand the molecular mechanisms of other types of directed migration we developed a method that allows examination of cellular response to acute mechanical stimulation based on brief (2 – 5 s) exposure to shear flow. This stimulation can be delivered in a channel while imaging cells expressing fluorescently-labeled biosensors to examine individual cell behavior. Additionally, cell population can be stimulated in a plate, lysed, and immunoblotted using antibodies that recognize active versions of proteins of interest. By combining both assays, one can examine a wide array of molecules activated by changes in subcellular localization and/or phosphorylation. Using this method we determined that acute mechanical stimulation triggers activation of the chemotactic signal transduction and actin cytoskeleton networks. The ability to examine cellular responses to acute mechanical stimulation is important for understanding the initiating events necessary for shear flow-induced motility. This approach also provides a tool for studying the chemotactic signal transduction network without the confounding influence of the chemoattractant receptor.
Migration of eukaryotic cells is biased by diverse chemical and physical cues in the environment, including gradients of soluble or substrate-bound chemoattractants, variable stiffness of the substrates, electric fields, or shear flow. Although there have been many advances in our understanding of the molecular mechanisms driving chemotaxis, less is known about other types of directed migration and how these diverse signals are integrated at the cellular level to produce a unified migratory response.
Directed migration toward an increasing concentration of a chemoattractant involves three behavioral components: motility, directional sensing, and polarity1. Motility refers to random movement of cells achieved by pseudopod protrusion. Directional sensing is the ability of a cell to detect the source of a chemoattractant, which can occur even in immobilized cells. Polarity refers to the more stable asymmetrical distribution of intracellular components between the leading and lagging edge of a cell, which leads to increased persistence in movement.
Cellular response to a chemoattractant depends on the activity of four conceptually defined regulatory networks: receptor/ G protein, signal transduction, actin cytoskeleton, and polarity1. Chemoattractant binding to the G protein-coupled receptor transmits the signal via heterotrimeric G proteins α and βγ to the downstream signal transduction network, which amplifies the directional signal. Multiple pathways within the signal transduction network act in parallel and feed into the actin cytoskeleton network to bias actin polymerization, and consequent pseudopod protrusion, in the direction of the gradient. Among important regulators of chemotaxis are Ras GTPase, TorC2, phosphoinositide 3-kinase (PI3K), phosphatase and tensin homolog (PTEN), and guanylyl cyclase. Feedback mechanisms within the signal transduction network and between the signal transduction and actin cytoskeleton networks further amplify the response. Finally, the poorly defined polarity network receives input from the actin cytoskeleton, and further biases the signal transduction network to promote persistent migration in the direction of the gradient.
Much of our mechanistic understanding of chemotaxis was made possible because of the development of fluorescently-tagged biosensors for various components of the regulatory networks. Many chemotaxis regulators have an asymmetrical distribution either of the regulatory molecule itself or its activity. For example, biosensors that recognize activated versions of small GTPases Ras and Rap1 – Ras-binding domains of Raf1 (referred to as RBD here) and RalGDS, respectively – localize to the leading edge of a chemotaxing cell2,3. Similarly, PI3K and its product phosphatidylinositol (3,4,5)-trisphosphate (PIP3), recognized by a pleckstrin homology (PH) domain, also show localization at the front of a cell4,5. In contrast, a 3-phosphatase PTEN, which converts PIP3 back to phosphatidylinositol (4,5)-bisphosphate, localizes to the lagging edge of the cell6. Importantly, these biosensors change their localization in response to global stimulation with a chemoattractant. Leading edge markers, which are cytosolic or on the tips of protrusions in a resting cell, relocalize to the cortex, whereas lagging edge markers, which have cortical localization and are absent from the tips of protrusions in a resting cell, become cytosolic after stimulation. Analysis of biosensor distribution in response to global stimulation with a chemoattractant minimizes the contribution of motility and polarity, which often confound the observations. Global or uniform stimulation of a cell suspension with a chemoattractant is also used as a tool to assess population-wide changes in protein activation, often detected by protein phosphorylation7,8,9. This biochemical assay is primarily used to obtain temporal information, whereas microscopy is used to gather both temporal and spatial information about the behavior of various components of the regulatory networks.
The signal transduction network incorporates features of an excitable system10,11. Responses to supra-threshold chemotactic stimuli are "all-or-none" and display refractory periods. Responses are also triggered stochastically and can show oscillatory behavior. Signal transduction events are localized to regions of the cortex that propagate as waves12,13,14,15. Front, or back, markers are recruited to, or dissociate from, the active zones of the propagating waves. Due to the refractory region trailing the active zone, the oppositely directed waves annihilate as they meet. The propagating signal transduction waves underlie the cellular protrusions that mediate cell migration10.
Much of the aforementioned information on chemotaxis came from the studies on the social amoeba Dictyostelium discoideum, although similar regulatory mechanisms are also applicable to neutrophils and other mammalian cell types16. Dictyostelium is a well-established model organism that has a robust chemotactic response during starvation, when thousands of single cells migrate toward an aggregation center, eventually forming a multicellular fruiting body containing spores. Chemotaxis is also essential during the single-cell growth stage of this organism for locating bacterial food sources. Importantly, migration of single Dictyostelium cells is remarkably similar to the migration of mammalian neutrophils or metastatic cancer cells, all of which undergo very rapid amoeboid-type migration. In fact, both the overall topology of the regulatory networks, as well as many of the individual signal transduction pathways involved in chemotaxis are conserved between Dictyostelium and mammalian leukocytes17. Furthermore, other cells, such as fibroblasts, use receptor tyrosine kinases (RTK) instead of GPCRs; however, RTKs may feed into similar networks.
In contrast to chemotaxis, thorough understanding of the signaling mechanisms that drive various other modes of directed migration is lacking. Similarly to cells migrating in a chemoattractant gradient several studies have reported activation and/or localization of typical leading edge markers, including actin polymerization, PIP3 and/or extracellular signal-regulated kinase (ERK) 1/2, at the front of cells undergoing directed migration in response to shear flow or changes in electric fields18,19,20,21. However, in these studies continuous exposure to the stimulus also resulted in cell migration, leaving open the question whether, for example, the leading edge markers localize specifically in response to a stimulus, or if they simply localize at the leading edge because of increased number of pseudopods at the front of a migrating cell.
We developed assays that allow us to observe the response of cells to acute mechanical perturbation delivered as shear flow both at the population level and as individual cells22. Similar to global stimulation with a chemoattractant, acute stimulation with shear flow allows the study of a cellular response to a mechanical stimulus without the confounding contribution from motility or polarity. Combining these biochemical and microscopic assays with genetic or pharmacological perturbations allows us to learn about how mechanical stimuli are perceived and transmitted. Moreover, this approach also provides a novel method for tapping into the system downstream of the chemoattractant receptor in the absence of a chemoattractant, thereby isolating the signal transduction and actin cytoskeleton networks from the receptor/G protein network.
Using the techniques described below we recently demonstrated that acute shear stress leads to activation of multiple components of the chemotactic signal transduction and actin cytoskeleton networks22. By applying the acute mechanical stimulus at varying intervals, we demonstrated that, similarly to chemoattractants, response to mechanical stimuli also exhibits features of an excitable system, including the all-or-none behavior of the response under saturating conditions and the presence of a refractory period. Finally, by combining mechanical and chemical stimulation we showed that the two stimuli share signal transduction and actin cytoskeleton networks, which likely allow for integration of multiple stimuli to bias cell migration.
1. Preparation of Solutions
2. Preparation of D. discoideum cells
NOTE: Maintain D. discoideum cells in HL-5 media either in tissue culture plates or in a suspension culture as previously described23. When necessary, transform cells with fluorescently-labeled biosensors according to standard electroporation protocols24. Various D. discoideum strains, as well as plasmids encoding biosensors or other genes of interest may be obtained from the Dicty Stock Center (dictybase.org).
3. Biochemical Analysis of Cell Response to Mechanical or Chemical Stimulation
4. Acute Mechanical Stimulation and Live Imaging of Single Cells on the Microscope
5. Continuous Mechanical Stimulation and Live Imaging of Single Cells on the Microscope
Temporal response of chemotaxis regulators to acute mechanical stimulation
To assess the response of D. discoideum cells to mechanical stimulation, adherent aggregation-competent cells were exposed to a brief pulse of shear flow. Aggregation-competent D. discoideum cells secrete cAMP, which can be sensed by neighboring cells. To overcome the contribution of cell-cell signaling, cells were treated with caffeine, which inhibits adenylyl cyclase in D. discoideum and thus prevents cAMP secretion28. Indeed, cells pre-treated with caffeine had very low basal activity of PKBR1 and ERK2, and showed a robust increase in the phosphorylation of the key residues of these kinases following 5 s stimulation with shear flow (Figure 1A). The response was transient and peaked around 10-15 s for PKBR1, and around 30 s for ERK2, similarly to previously published findings for activation of these proteins with a chemoattractant7.
Although it is difficult to evaluate the efficiency of the response considering the low basal level, preliminary studies that led to the development of this assay, compared stimulation with shear flow alone (or with a vehicle) to shear flow in the presence of a chemoattractant cAMP (Figure 1B). This analysis did not show an increase in the response with the cAMP, suggesting that the response of the signal transduction network to shear flow is saturated. Although in this assay cAMP did not increase phosphorylation of PKBR1, cells' response to chemoattractant can be observed using a standard stimulation protocol where aggregation-competent cells are kept in suspension, stimulated with cAMP, and lysed at various time points following stimulation. As shown in Figure 1C, under these conditions there is a transient increase in PKBR1 phosphorylation in response to chemoattractant, but not vehicle. The peak response is observed at 30 s in this assay because the temperature of the cell suspension during the assay is ~9 °C, compared to ~22 °C for mechanical stimulation assay described above26.
Spatiotemporal response of leading and lagging edge markers to acute mechanical stimulation
Since the population assay above only provides temporal information about the behavior of chemotaxis regulators, cells were also exposed to a brief mechanical stimulus while being observed with a microscope. This assay can be performed either with aggregation-competent or vegetative D. discoideum cells expressing various fluorescently-labeled biosensors whose localization was defined in cells stimulated with a chemoattractant. Two leading edge markers, PH domain of Crac and LimEΔcoil, which are recruited by PIP3 or newly-polymerized actin, both showed mostly cytosolic localization in resting cells as previously reported (Figure 2A, Supplemental Movie 1)4,29. In cells that were basally active, these biosensors could also be seen on the tips of the pseudopods. Following stimulation with shear flow for 2 s, the biosensors rapidly relocalized to the cortex with a peak at ~6 to 10 s, and returned to the cytosol by ~30 s. In contrast, a lagging edge marker PTEN localized at the cortex before stimulation (Figure 2A). After a brief pulse with shear flow, cytosolic PTEN intensity increased, albeit with slower dynamics than for the leading edge biosensors. A change in biosensor localization from the cytosol to the cortex, and vice versa, is clearly seen as a change in the cytosolic intensity allowing for simple quantification of the response.
The observed behavior of the biosensors in response to acute mechanical stimulation is consistent with leading and lagging edge localization dynamics in response to stimulation with uniform chemoattractant. This behavior was not unique to the three biosensors shown. As previously published, similar changes in localization were also observed for leading edge markers RBD and RalGDS, which recognize activated Ras and Rap1, respectively, as well as for another lagging edge marker CynA22,30.
A similar assay can be used to assess the effects of various inhibitors by a simple modification of the experimental setup from a single input line to a double one. Using this method, the cells can be first exposed to control conditions, and then switched to the buffer that contains the desired test agent. For example, addition of actin-depolymerizing drug LatA blocked the response of RBD, as well as LimEΔcoil, to acute mechanical stimulation (Figure 2B).
Global response precedes cell migration under prolonged stimulation with shear flow
The approach described here could also be adapted to study effects of shear flow on D. discoideum migration. In fact, if the flow was not shut off after 2 s but remained on for the duration of the experiment, vegetative cells showed directed migration against the flow (Figure 3, Supplemental Movie 2). It should be noted that the shear flow necessary to elicit a migratory response was lower than the pressure that was typically used to achieve a global response with acute stimulation in vegetative cells (for example, as seen in Figure 2B). However, even at the lower pressure, cells displayed a robust uniform response, as measured by a change in LimEΔcoil localization, that preceded any change in the position of the cell itself. Thus, these experiments clearly showed that 1) the global response does not depend on the movement of the cell, and 2) the global response precedes directed migration.
Alternative approaches of testing response to acute mechanical stimulation
Although the use of a flow-through chamber has clear advantages for the study of the response to acute mechanical stimulation, we also validated two additional assays for testing the response of individual cells to acute mechanical stimulation. As shown in Figure 4, LimEΔcoil rapidly and transiently re-localized from the cytosol to the cortex when cells were stimulated by bolus addition of buffer delivered either by a micropipette (Figure 4A) or manually using bulk buffer addition with a pipette (Figure 4B). It should be noted that a clear disadvantage of both of these assays is that the exact amount of shear force delivered to the cell is unknown, and cannot be easily varied. However, for situations where switching between mechanical and chemical stimuli is desired, bulk buffer addition offers a solid alternative to the stimulation in the flow device.
Figure 1: Representative results for biochemical assessment of the response of D. discoideum cells to acute mechanical or chemical stimulation. Aggregation-competent cells were exposed to mechanical or chemical stimuli, lysed at the indicated time points, and immunoblotted using antibodies that recognize phosphorylated PKBR1 or ERK2. (A) Adherent cells were stimulated on an orbital shaker for 5 s. The membrane was stained with Coomassie Brilliant Blue (CBB) to show equal protein loading. (B) Adherent cells were stimulated by manual movement of the plate in a cross-wise manner for approximately 5 s following chemical stimulation due to addition of 1 µM cAMP or buffer (vehicle), or without any chemical stimulation (-). The two immunoblots show the extent of variation in the basal activation of PKBR1 seen at time 0. Occasionally, PKBA activation could also be detected by this technique, as shown in the lower panel. (C) Suspension cells were stimulated with 1 µM cAMP or buffer (vehicle). Part (A) of this figure has been modified from Artemenko et al. (2016)22. Please click here to view a larger version of this figure.
Figure 2: Representative results for acute mechanical stimulation and live imaging of single cells on the microscope. (A) Aggregation-competent D. discoideum cells expressing RFP-tagged LimEΔcoil, or GFP-tagged PH-Crac or PTEN were stimulated with unidirectional laminar flow at 15 dyn/cm2 for 2 to 5 s. Images were collected every 3 s. Representative cells showing translocation of the biosensors in response to mechanical stimulation are shown. Accumulation of each biosensor at the cortex was quantified as the inverse of the mean cytoplasmic intensity normalized for time 0. The average response of 18 (LimEΔcoil), 20 (PH-Crac), or 6 (PTEN) cells is shown. Values are mean ± SE. (B) Vegetative cells expressing RFP-tagged LimEΔcoil-RFP and GFP-tagged RBD were treated with vehicle or 5 µM LatA for at least 15 min, and then stimulated with unidirectional laminar flow at 41 dyn/cm2 for 2 s. Images were collected every 3 s. RBD-GFP and LimEΔcoil-RFP accumulation at the cortex was quantified as in (A). Values are mean ± SE. The number of cells analyzed is indicated beside each condition. Scale bar = 10 µm. This figure has been modified from Artemenko et al. (2016)22. Please click here to view a larger version of this figure.
Figure 3: Representative results for the response of D. discoideum cells to prolonged stimulation with flow. (A) Vegetative cells expressing RFP-tagged LimEΔcoil were exposed to continuous unidirectional laminar flow at 15 dyn/cm2 and imaged every 3 s. Tracks of 11 cells are shown in (B). Scale bar = 10 µm. This figure has been modified from Artemenko et al. (2016)22. Please click here to view a larger version of this figure.
Figure 4: Representative results for alternative approaches to testing response to acute mechanical stimulation. (A) Vegetative D. discoideum cells expressing RFP-tagged LimEΔcoil were exposed to a micropipette (*) basally releasing assay buffer at a slow rate. A brief increase in flow rate was achieved by rapid delivery of a bolus of assay buffer at time 0. Images were collected every 3 s. (B) Vegetative D. discoideum cells expressing RFP-tagged LimEΔcoil plated as a small drop in a microscopy chamber were mechanically stimulated by addition of a large volume of buffer to the chamber. Images were collected every 3 s. Scale bar = 10 µm. Part (A) of this figure has been modified from Artemenko et al. (2016)22. Please click here to view a larger version of this figure.
Supplemental Movie 1: Acute mechanical stimulation triggers rapid and transient translocation of LimEΔcoil-RFP or PH-Crac-GFP from the cytosol to the cortex in aggregation-competent D. discoideum cells expressing these biosensors. Unidirectional laminar flow was turned on for 5 s at time 0 and cells were imaged at 3 s intervals. Playback speed is 5 frames/s. Two examples for each cell line are shown. Scale bar = 10 µm. This movie corresponds to Figure 2A and has been modified from Artemenko et al. (2016)22. Please click here to download this file.
Supplemental Movie 2: Continuous mechanical stimulation triggers rapid and transient translocation of LimEΔcoil-RFP from the cytosol to the cortex prior to migration of cells against the direction of the flow. Vegetative cells expressing LimEΔcoil-RFP were exposed to continuous shear stress at 15 dyn/cm2 starting at time 0 and imaged at 3 s intervals. Playback speed is 10 frames/s. Scale bar = 10 µm. This movie corresponds to Figure 3 and has been previously published in Artemenko et al. (2016)22. Please click here to download this file.
The methods described here offer a convenient way to assess both population and individual cell behavior in response to shear flow. Importantly, while previous studies analyzed localization of leading and lagging edge markers during migration, the current approach allows investigation of immediate effects by applying the shear flow acutely. Using this method we demonstrated that, in fact, the initial response of cells to shear flow does not require cell migration. Instead, the rapid and transient response to the initial shear flow stimulus precedes the directional migration seen with prolonged exposure to shear flow, similarly to the initial global response seen with a chemoattractant gradient.
The biochemical and microscopic approaches yield complementary data even though each method has distinct advantages and disadvantages. Stimulation followed by cell lysis and immunoblotting of PKBs, KrsB, and ERK, for example, analyzes an entire population of cells and thus averages cell-to-cell variation, unlike an assay that examines individual cell behavior. However, population-based assays tend to mask subtle changes in cell behavior that can be easily observed by analyzing individual cells. Additionally, the biochemical assay described here is only effective with aggregation-competent cells, for reasons that will be discussed later. In contrast, the microscopy-based assay of the relocalization of RBD, RalGDS, PH-Crac, LimEΔcoil, and PTEN, for example, between the cortex and cytosol is effective for both vegetative and aggregation-competent cells, and thus allows for observations that are broadly applicable to cells with varying degrees of polarization. What makes the two approaches complementary is the fact that they examine different sets of available leading/lagging edge markers, thus expanding the coverage of the signal transduction and actin cytoskeleton networks tested with the shear flow assay.
It remains unclear why vegetative cells, which respond very robustly in microscopy-based assays, do not respond to stimulation followed by cell lysis and immunoblotting. One possibility is that the amount of shear force applied to cells when the plate is rotated does not match the force experienced by the cells in a flow chamber. Developed cells, in contrast, might have a lower threshold for activation, and, thus, respond under either condition. It is unlikely that the biosensors whose activity is measured by the biochemical assay are not expressed or are not activated in vegetative cells, since stimulation of vegetative cells with folic acid leads to robust activation of both PKBR1/PKBA and ERK2 (data not shown). Moreover, vegetative cells show clear recruitment of PH-Crac, which reflects PIP3 accumulation, in the microscopy-based assay. Since PKBA recruitment also depends on PIP3, it seems unlikely that PKBA would not respond to acute mechanical stimulation, unless the conditions in the biochemical assay are not optimal as mentioned above. This remains an area of active investigation.
The biochemical analysis of chemotaxis regulators required the presence of caffeine throughout the experiment. Originally caffeine was added to prevent cell to cell signaling due to secretion of cAMP. However, it appears that caffeine has another role besides inhibition of adenylyl cyclase (ACA) since ACA-null cells still required caffeine for phosphorylation of PKBR1 in response to acute mechanical stimulation. Caffeine has been previously shown to block TorC2 activity26. It is possible that inhibition of TorC2 blocked some basal motility of the cells, and thus lowered the basal activation of PKBR1 and other components of signal transduction and actin cytoskeleton networks. Low basal activity was imperative for observing the response to shear flow. In fact, when cells were collected at earlier time points during development, they displayed increased basal activity and a reduced shear-flow induced response. Interestingly, it is known that vegetative cells have proportionally more PKBA activity and less PKBR1 compared to developed cells31. It is possible that the basal state is regulated somewhat differently in vegetative and aggregation-competent cells, further contributing to the lack of a response of vegetative cells in the biochemical assay. Curiously, when cells were collected at later points of development, they also had a reduced response, likely due to the strong influence of polarity on the localization and activation of various chemotaxis regulators examined in this assay.
Stimulation of cells in a microscopy chamber revealed that both the strength and the duration of stimulus contribute to maximal response22. In other words, a maximal response can be achieved even with a low shear force if it is applied for a prolonged period of time (10 s versus 2 s). This observation explains why cells have an initial global response when they are first exposed to a continuous, but weak, stimulus that leads to shear flow-induced migration. With the current apparatus, we were unable to generate low enough shear flow to investigate the lower end of the range.
Perhaps, the most important implication of the studies conducted using acute mechanical stimulation is that both mechanical and chemical stimuli appear to feed into common signal transduction and actin cytoskeleton networks. Although we showed that the two stimuli integrate using bulk buffer addition for the mechanical stimulation, future studies will aim to develop a system where chemoattractant can be delivered rapidly in the flow-through channel, which would be a much more versatile and powerful way to assess integration of mechanical and chemical stimuli. Unfortunately, chemoattractant addition using the current two-line setup is associated with a second shear flow stimulus because the chemoattractant has to be delivered in the presence of flow. A viable alternative may be laser-stimulated release of a chemoattractant from a caged precursor as was successfully shown for cAMP by Westendorf et al.32. In the future, it would also be interesting to examine integration of other stimuli, for example, shear flow and variable electric fields, or shear flow and variable substrate stiffness. The latter example is interesting because it involves two types of mechanical stimulation, although the initial signal reception might differ between them. Confirming that all stimuli that induce directed migration share the same signal transduction network and vary only in how the stimulus is perceived will explain how cells can navigate in complex environments. Finally, we already demonstrated that acute stimulation with shear flow leads to spreading of human neutrophil-like cells22. Future work will further examine localization and activation of various components of the signal transduction and actin cytoskeleton networks with mechanical stimuli in mammalian cells.
The authors have nothing to disclose.
This work was supported by National Institutes of Health grant R35 GM118177 to PND.
Reagents | |||
Dextrose | Fisher | D16-1 | Use to prepare HL-5 media and SM plates (steps 1.1, 1.2) |
Proteose peptone | Fisher | DF0120-17-6 | Use to prepare HL-5 media (step 1.1) |
Yeast extract | Fisher | 50-550-445 | Use to prepare HL-5 media and SM plates (steps 1.1, 1.2) |
Na2HPO4·7H2O | Fisher | S373-500 | Use to prepare HL-5 media, and 10X Phosphate Buffer (steps 1.1, 1.3) |
KH2PO4 | Fisher | P386-500 | Use to prepare HL-5 media, SM plates, and 10X Phosphate Buffer (steps 1.1-1.3) |
Streptomycin (dihydrostreptomycin sulfate) | Fisher | ICN10040525 | Use to prepare HL-5 media (step 1.1) |
Peptone (Bacto) | Fisher | DF0118-17-0 | Use to prepare SM plates (step 1.2) |
K2HPO4 | Fisher | P288-100 | Use to prepare SM plates (step 1.2) |
Agar | Fisher | BP1423-500 | Use to prepare SM plates (step 1.2) |
MgSO4 | Fisher | M65-500 | Use to prepare DB Buffer (step 1.4) |
CaCl2 | Fisher | C79-500 | Use to prepare DB Buffer (step 1.4) |
Caffeine | Fisher | O1728-500 | Use to prepare caffeine (step 1.5) |
cAMP (EMD Millipore Calbiochem Adenosine 3 ft.,5 ft.-cyclic Monophosphate, Sodium Salt) | Fisher | 11-680-1100MG | Use to prepare cAMP (step 1.6) |
Folic acid | Sigma | F7876 | Use to prepare folic acid (step 1.7) |
Tris base | Fisher | BP152-500 | Use to prepare 3X sample buffer (step 1.8) |
Sodium dodecyl sulfate (SDS) | Fisher | BP166-500 | Use to prepare 3X sample buffer (step 1.8) |
Glycerol | Fisher | G33-500 | Use to prepare 3X sample buffer (step 1.8) |
Dithiothreitol (DTT) | Bio-Rad | 1610610 | Use to prepare 3X sample buffer (step 1.8) |
Bromophenol blue | Bio-Rad | 1610404 | Use to prepare 3X sample buffer (step 1.8) |
NaF | Fisher | S299-100 | Use to prepare sample buffer with protease and phosphatase inhibitors (step 1.8) |
Na3VO4 | Fisher | 50-994-911 | Use to prepare sample buffer with protease and phosphatase inhibitors (step 1.8) |
Sodium pyrophosphate decahydrate | Fisher | S390-500 | Use to prepare sample buffer with protease and phosphatase inhibitors (step 1.8) |
Complete EDTA-free protease inhibitor cocktail (Roche) | Sigma | 11873580001 | Use to prepare sample buffer with protease and phosphatase inhibitors (step 1.8) |
Latrunculin A | Enzo Life Sciences | BML-T119-0100 | Use to prepare Latrunculin A (step 1.9) |
4-15% Tris-HCl polyacrylamide gel | Bio-Rad | 3450029 | Use for immunoblotting (step 3.3) |
Polyvinylidene fluoride membrane | Bio-Rad | 1620177 | Use for immunoblotting (step 3.3) |
Phospho-PKC (pan) (zeta Thr410) (190D10) Rabbit antibody | Cell Signaling | 2060 | Primary antibody for use in immunoblotting (step 3.3) |
Phospho-p44/42 MAPK (Erk1/2) (Thr202/Tyr204) (D13.14.4E) XP antibody | Cell Signaling | 4370 | Primary antibody for use in immunoblotting (step 3.3) |
Rabbit IgG HRP Linked Whole Ab (from Donkey) | GE Healthcare | NA934-100UL | Secondary antibody for use in immunoblotting (step 3.3) |
Enhanced chemiluminescence substrate (Clarity Western ECL Substrate) | Bio-Rad | 1705060 | Use for immunoblotting (step 3.3) |
Stripping buffer (Restore Plus Western blot stripping buffer) | Pierce | PI46430 | Use for immunoblotting (step 3.3) |
Coomassie Brilliant Blue | Fisher | PI20278 | Use for immunoblotting (step 3.3) |
K. aerogenes strain (non-pathogenic) | Dicty Stock Center (dictybase.org) | ||
Name | Company | Catalog Number | Comments |
Materials and Equipment | |||
Orbital shaker (model G-33, or a comparable alternative) | New Brunswick Scientific | Use to grow K. aerogenes (step 2.1.1), and to basalate and stimulate D. discoideum cells (step 3). The radius of gyration for this shaker is 9.5 mm. | |
10 cm Petri dish | Fisher | FB0875712 | Use to prepare SM plates (step 1.2) |
Hemocytometer | Fisher | 02-671-51B | Use to count D. discoideum cells (step 2.1.2) |
35 mm dish (Corning Falcon Easy-Grip Tissue Culture Dish) | Fisher | 08-772A | Use to plate D. discoideumcells for mechanical stimulation followed by cell lysis (step 3.1.1) |
Polystyrene cup (5 mL) | VWR | 13915-985 | Use to stimulate D. discoideum cell suspension with a chemoattractant (step 3.2.2) |
Fluidic unit with pump (ibidi Pump System) | Ibidi | 10902 | Use to deliver mechanical stimulation to D. discoideum cells in a channel (steps 4.1, 4.2, and 5) |
Slide with a channel (μ-Slide III 3in1 ibiTreat: #1.5 polymer coverslip, tissue culture treated, sterilized) | Ibidi | 80316 | Use to plate D. discoideum cells for mechanical stimulation delivered by a fluidic device (steps 4.1, 4.2, and 5) |
50 mL reservoirs (Ibidi Reservoir Holder for Fluidic Unit) | Ibidi | 10978 | Use to setup the fluidic device for delivering mechanical stimulation to D. discoideum cells in a channel (steps 4.1, 4.2, and 5) |
Lines for the fluidic unit (Perfusion Set YELLOW-and-GREEN) | Ibidi | 10964 | Use to setup the fluidic device for delivering mechanical stimulation to D. discoideum cells in a channel (steps 4.1, 4.2, and 5). Note: the two lines can also be cut from the 1.6 mm tubing (catalog number 10842). |
Line for the drain (1.6 mm ID tubing) | Ibidi | 10842 | Use to setup the fluidic device for delivering mechanical stimulation to D. discoideum cells in a channel (steps 4.1, 4.2, and 5). |
Zeiss Observer.Z1 inverted microscope equipped with a 40X/1.3 oil objective and a 20X/0.3 air objective (or a comparable alternative) | Zeiss | Used to image D. discoideum cells with phase-contrast or fluorescence illumination (steps 4 and 5) | |
UltraView spinning disk confocal microscope equipped with a 40×/1.25–0.75 oil objective (or a comparable alternative) | Perkin-Elmer | DM 16000 | An alternative used to image D. discoideum cells (step 4.1.4) |
FemtoJet Microinjector (Eppendorf; model 5247, or a comparable alternative) with Eppendorf InjectMan | Eppendorf | 5252000021D and 5192000027 | Use to deliver mechanical stimulation to D. discoideum cells by a micropipette (step 4.3). Note: catalog number are for the newest version of the equipment (4i). |
Micropipette (Femtotip; 1 μm outside diameter, 0.5 μm inside diameter ) | Eppendorf | 930000035 | Use to deliver mechanical stimulation to D. discoideum cells by a micropipette (step 4.3) |
Microloader tips (Eppendorf Femtotips Microloader Tips for Femtojet Microinjector) | Eppendorf | 5242956.003 | Use to fill the micropipette (femtotip) with buffer (step 4.3.1) |
1-well chamber (Thermo Scientific Nunc Lab-Tek Chambered Coverglass) | Fisher | 12-565-472 | Use to plate D. discoideum cells for mechanical stimulation delivered by a micropipette (step 4.3.2) |
8-well chamber (Thermo Scientific Nunc Lab-Tek II Chambered Coverglass) | Fisher | 12-565-338 | Use to plate D. discoideum cells for mechanical stimulation delivered by bulk buffer addition (step 4.4.1) |
Name | Company | Catalog Number | Comments |
Software | |||
Image Analysis Software (Fiji) | NIH | https://fiji.sc/ | Use to quantify response to mechanical stimulation (step 4.5) |
Migration analysis software (Tracking Tool PRO) | Gradientech | http://gradientech.se/tracking-tool-pro/ | Use to quantify cell speed and persistence (step 5.4) |