Here we describe the dissection of the crayfish abdominal nerve cord. We also demonstrate an electrophysiological technique to record fictive locomotion from swimmeret motor neurons.
Here we demonstrate the dissection of the crayfish abdominal nerve cord. The preparation comprises the last two thoracic ganglia (T4, T5) and the chain of abdominal ganglia (A1 to A6). This chain of ganglia includes the part of the central nervous system (CNS) that drives coordinated locomotion of the pleopods (swimmerets): the swimmeret system. It is known for over five decades that in crayfish each swimmeret is driven by its own independent pattern generating kernel that generates rhythmic alternating activity 1-3. The motor neurons innervating the musculature of each swimmeret comprise two anatomically and functionally distinct populations 4. One is responsible for the retraction (power stroke, PS) of the swimmeret. The other drives the protraction (return stroke, RS) of the swimmeret. Motor neurons of the swimmeret system are able to produce spontaneously a fictive motor pattern, which is identical to the pattern recorded in vivo 1.
The aim of this report is to introduce an interesting and convenient model system for studying rhythm generating networks and coordination of independent microcircuits for students’ practical laboratory courses. The protocol provided includes step-by-step instructions for the dissection of the crayfish’s abdominal nerve cord, pinning of the isolated chain of ganglia, desheathing the ganglia and recording the swimmerets fictive motor pattern extracellularly from the isolated nervous system.
Additionally, we can monitor the activity of swimmeret neurons recorded intracellularly from dendrites. Here we also describe briefly these techniques and provide some examples. Furthermore, the morphology of swimmeret neurons can be assessed using various staining techniques. Here we provide examples of intracellular (by iontophoresis) dye filled neurons and backfills of pools of swimmeret motor neurons. In our lab we use this preparation to study basic functions of fictive locomotion, the effect of sensory feedback on the activity of the CNS, and coordination between microcircuits on a cellular level.
The swimmerets of crayfish serve a function in posture control and beat rhythmically when the animals swim forward, ventilate their burrows or females aerate their eggs 5, 6. The swimmerets of the signal crayfish, Pacifastacus leniusculus, occur in pairs from the second to the fifth abdominal segment, with one limb on each side of the abdomen 7. The central nervous system produces on its own the rhythmic motor patter which drives the swimmeret movement in the intact animal as well as in the isolated nerve cord preparation. When there is no sensory feedback or descending input present the rhythmic motor pattern produced is called fictive locomotion 1, 2. In the swimmeret system this motor pattern does not differ in any parameter from the activity of the swimmerets measured in the intact animal.
The movement of each swimmeret is driven by a microcircuit that is located in and restricted to one corresponding hemiganglion 1 – 3. In each microcircuit there is a pattern generating kernel that comprises five identified non spiking interneurons. They can be functionally characterized as being either Inhibitor of Power Stroke (IPS) or Inhibitor of Return Stroke (IRS) 8. These IPS and IRS interneurons are not endogenous oscillators, rather their alternating activity is driven by reciprocal inhibition 9. Because these interneurons inhibit the swimmeret motor neurons directly, the alternating PS-RS movement is generated 10. Locomotion however, does not only require the generation of activity, but also coordination of the different independent microcircuits. In the swimmeret system such coordination is established by the coordinating microcircuit which ensures that limbs are active at correct times. This microcircuit is built by three identified neurons in each segment 11-15.
This protocol provides for the first time a step-by-step dissection guide to isolate the chain of ganglia (T4 to A6, Figure 1). We show how to pin the isolated abdominal nerve cord and desheathe each ganglion. In this isolated nervous system preparation, the neurons responsible for swimmeret movement are ready for use in electrophysiological and morphological experiments. The second part of this protocol demonstrates the main features of the swimmeret motor pattern. This includes a step-by-step guide to extracellularly record the activity of swimmeret motor neurons. Axons of RS motor neurons project through the anterior branch of nerve N1, while axons of PS motor neurons project through the posterior branch of the same nerve (Figure 1) 4. Therefore their activity can be recorded from these branches with differential pin electrodes.
Figure 1: Isolated nervous system from thoracic ganglion 4 (T4) to abdominal ganglion 6 (A6) and a schematic diagram of it. T4: thoracic ganglion 4; T5: thoracic ganglion 5; A1, A2 … A6 abdominal ganglion 1, abdominal ganglion 2 … abdominal ganglion 6; N1: nerve N1; N2: nerve N2; N3: nerve N3; PS: power-stroke; RS: return-stroke. Directional abbreviations: A = anterior; P = posterior.
This dissection procedure and the electrophysiological technique demonstrated are convenient for undergraduate students and may complement student practical courses in physiology. The isolated chain of ganglia has been used in a number of experiments to study nervous system function, coordination, or modulation of swimmeret microcircuits 6 as well as neuronal control of adaptive behavior in locomotion 16, 17. The crayfish swimmeret system thus provides an enormous amount of interesting teaching or training opportunities which all begin with the dissection of the ventral nerve cord of crayfish and extracellular recording of the fictive motor pattern.
This dissection procedure is in accordance with the European Communities Council Directive of 22nd September 2010 (2010/63/EU).
1. Preparation
Figure 2: Materials and tools used for the dissection, pinning and desheathing of the nerve cord.
(1) big bucket filled with ice; (2) crayfish saline; (3) saline dispenser; (4) dissection microscope; (5) dissection dish; (6) strong scissors; (7) forceps (8) spring scissors; (9) Petri dish lined with clear sylgard; (10) fixing pins; (11) cold lamp source.
2. Gross Dissection
3. Fine Dissection
4. Pinning the Nerve Cord into the Petri Dish
NOTE: Use small pins cut from stainless steel wire (see supplements) to pin the nerve cord. Touch only the nerve ending with the forceps and do not squeeze the connectives or ganglia.
5. Desheathing the Ganglia
6. Extracellular Recordings from Motor Neurons
With the simultaneous extracellular recordings from RS and PS, motor neurons of one ganglion, the alternating activity of these motor neuron pools, can be monitored (Figure 18), representing the fictive locomotion pattern.
Figure 18: Schematic of one ganglion and placement of differential pin electrode. Extracellular recording of RS motor neurons (upper trace) and PS motor neurons (lower trace).
The extracellular PS activity of ipsilateral PS 2 to PS 5 motor neurons highlights interesting aspects of intersegmental coordination in the swimmeret system (Figure 19A).
First, the activity always starts with a PS burst in A5 (Figure 19A, 4th trace) and the excitation wave propagates in the anterior direction (Figure 19A, green line). Second, the period (which is the time measured from the onset of one burst to the onset of the next burst) in each segment remains constant (Figure 19A, cyan arrow). This is true, as long as the information flow from one ganglion to the next is intact and the experimental conditions do not change.
In different preparations or under different experimental conditions the periods and burst durations can vary substantially: from periods of 0.25 to 1 sec. In order to compare these parameters between different preparations, they need to be normalized and graphed in a phase histogram (Figure 19B). This reveals the third interesting aspect of the motor pattern: the phase-lag between segments, the intersegmental delay, remains constant and independent of the frequency of the rhythm.
To calculate a phase histogram, the following measurements and calculations are necessary:
First, a reference trace has to be chosen. Usually we use the PS trace of the most posterior ganglion (e.g., PS 5) as a reference (being time 0) for a phase histogram of the swimmeret rhythm recorded across several segments (Figure 19A).Then, measure the period (in ms) of the rhythm from the beginning of one PS 5 burst (time 0, Figure 19A, orange dotted line) to the beginning of the next PS 5 burst (Figure 19A, cyan arrow).Within this cycle, measure the latencies (in ms) between the start of the PS 5 burst (time 0) and the start (burst onset, Figure 19A and B, orange arrows) and end (offset Figure 19A and B, violet arrows) of the PS burst in each of the other ganglia. Therefore to calculate the phase onset and offset for each burst the latencies are divided by the concurrent period. These measurements will result in numeric values between 0 and 1. Finally, plot these values in a phase histogram as shown in Figure 19B.
The resulting phase histogram (Figure 19B) contains information about the duty cycle of the PS burst in each segment. And the intersegmental phase-lag of ~0.25 between neighboring segments is clearly visible.
Figure 19: (A) Schematic of electrode placement and extracellular recording of ipsilateral PS 5 to PS 2. (B) Measurements and calculations needed for the phase histogram. The phase histogram calculated from ten consecutive bursts (n = 10) shows the intersegmental phase delay of ~0.25.
For more advanced experimenters, intracellular recordings with sharp microelectrodes from the dendrites of motor neurons can be useful. The membrane potentials of individual intracellularly recorded PS motor neurons show in-phase oscillations with the extracellularly recorded activity of all PS motor neurons of the same hemiganglion (Figure 20, gray panels). Alternatively, RS motor neurons or interneurons can be recorded intracellularly in the same way (data not shown).
Figure 20: Schematic of electrode placement. The membrane potential of one intracellularly recorded PS motor neuron (upper trace) oscillates in phase (gray panels) with the extracellularly recorded PS activity (lower trace).
For identification of intracellularly recorded neurons (interneurons or motor neurons), cells can be dye filled using sharp microelectrodes and iontophoresis (see discussion). In Figure 21, two intracellularly dye filled PS motor neurons are shown. Their ventral somata are located posterior to the base of the nerve N1. The primary neurite projects anteriorly (Figure 21B-2) and branches within the Lateral Neuropil (Figure 21A and B-3); the axon projects through the posterior branch of the nerve N1 to the swimmeret musculature (Figure 21B-4).
Figure 21: (A) Schematic of an abdominal ganglion. (B) Two intracellularly stained PS motor neurons. (1) somata; (2) primary neurites; (3) dendritic branching in the lateral neuropil; (4) axons project through the posterior branch of the nerve N1; Bar = 100 µm.
For less advanced experimenters, or those who want to study the morphology of the abdominal ganglion, backfills from the PS and RS motor neuron pools via the nerve N1, are an interesting exercise. In Figure 22, the RS and PS motor neurons of one hemiganglion were stained with Co2+ (RS) and Ni2+ions (PS), respectively. Somata of PS motor neurons are located posterior to the base of the nerve N1 (Figure 22-1). All somata of RS motor neurons are located anterior to the base of the nerve N1 (Figure 22-2).
Figure 22: Backfills from the anterior (orange, Co2+) and posterior (blue, Ni2+) branch of nerve N1. (1) Somata of PS motor neurons; (2) somata of RS motor neurons. Bar = 100 µm.
Figure 3: Removal the claws (1) and uropods (2). Red lines (1) and (2) indicate positions of cuts. Bar = 5 cm.
Figure 4: (A) The animal is pinned ventral side up and fixed at the telson. (B) The crayfish is exsanguinated through the claw opening with cold saline. Bars = 5 cm.
Figure 5: (A) Decapitation and (B) removal of walking legs. Red lines indicate positions of cuts. Bars = 1 cm.
Figure 6: (A, B, C and D) Removal of the anterior and the lateral parts of the cephalothorax. E. Opening of the abdomen along the lateral side. Red lines (1), (2), (4), and (5) indicate positions of cuts. (3) Digestive gland. Red arrows point to the already opened abdominal cavity. Bars = 1 cm.
Figure 7: (A) The specimen is grabbed at an opening of the walking legs (red arrows). (B) The dorsal muscle strands (1) are transected while the specimen is opened. White arrow depicts the direction in which the sternal plate is pulled. (C) Overview of the abdominal cavity with the sternal artery (2) and nerve cord (3).
Figure 8: Transverse view of the crayfish abdomen with fixed dorsal muscle strands (1) and sternal artery (2); Red lines (3) and (4) indicate positions of cuts. Bars = 5 mm.
Figure 9: Dorsal and ventral parts of the abdomen are separated from each other. (1) Red line indicates position of cut. Sternal plate (2) with ventral nerve cord; dorsal part of the abdomen (3).
Figure 10: (A) Positions of the forceps to remove the anterior cephalothoracic sterna. (B) Red lines (1) and (2) indicate where to cut the muscles between the remaining cephalothoracic sterna. (C) The thoracic nerves are transected at the red lines (3) to isolate the thoracic ganglia from the surrounding tissue. Red line (4) indicates the cut between T3 and T4. Bars = 5 mm.
Figure 11: (A and B) View of the sternal plate at A2. The nerve N1 is isolated from the tissue with a cut along the posterior sternal cuticular infolding (1) and anterior to both sternal cuticular infoldings (B 2). (C) Higher magnification of the region around A2, with the isolated nerve N1. (D) Isolation of the nerve N1 on the contralateral side with similar cuts. Red lines (2) and (3) indicate positions of cuts; (1) anterior and posterior sternal cuticular infoldings; Bars = 5 mm.
Figure 12: (A and B) A6 is isolated from the tissue and the nerve cord can be lifted at the nerves of A6. (C) All connections of the abdominal ganglia to the ventral abdominal artery are transected. (D) Isolated nerve cord is transferred into a Petri dish lined with clear sylgard and filled with saline. Red lines indicate positions of cuts. Bars = 5 mm.
Figure 13: Lateral view of one ganglion. Identification of the dorsal and ventral side (black line) of the nerve cord. Bar = 5 mm
Figure 14: The anterior branch of the nerve N1 is separated from the posterior branch. Bar = 5 mm.
Figure 15: Directions for desheathing of an abdominal ganglion (A) Position of the first small cut through the sheath of the connectives (red arrow), placed lateral and posterior to the ganglion. The subsequent cut through the sheath above the connective is marked by the red line (1). (B) Red lines (1) and (2) mark the cuts along the lateral borders of the ganglion. The sheath can afterwards be pulled from the ganglion. Bars = 1 mm.
Figure 16: (A) Overview of the recording setup. (B) Materials and tools needed for extracellular recordings. C. Equipment necessary for electrophysiological recording. (1) cold lamp source; (2) faraday cage; (3) stereo microscope; (4) air-table; (5) microscope table; (6) mirror; (7) differential pin electrodes; (8) syringe filled with petroleum jelly; (9) modeling clay; (10) forceps; (11) liquid waste disposal; (12) digitizer; (13) extracellular amplifier; (14) computer, equipped with recording software and monitor.
Figure 17: (A and B) Position of recording (1) and reference (2) pin electrode. (C and D) The posterior branch of the nerve N1 is bend around the recording electrode. E. The base (4) of the recording electrode is isolated with petroleum jelly. F. The complete recording electrode is isolated with petroleum jelly from the bath solution. (3) Syringe filled with petroleum jelly. Bars = 2 mm.
The anatomy of crayfish and their abdominal ganglia has been described previously 5, 18, 19, 20 and it is recommended to become familiar with them prior to the dissection in order to avoid cutting of important nerves.
It is critical to keep the preparation at temperatures below 23 °C to prevent degradation of the isolated nerve cord. This can be achieved easily by replacement of the bathing solution every 20–30 min with cold crayfish saline. Under these circumstances the chain of ganglia can be used for electrophysiological experiments for up to 12 hr.
Sometimes swimmeret motor neurons are inactive and show no spontaneous bursting activity. The cholinergic agonist carbachol is used to induce bursting activity in these preparations. Dissolved in cold crayfish saline, bath applications of 1-3 µM carbachol are sufficient to activate the swimmeret rhythm 21.
The fictive locomotion and especially the coordination of the limbs recorded in this system provide a lot of information about the cellular properties of rhythmic activity and coordination. In this system the neuronal components 8-10 of the local microcircuits are identified and additionally the coordinating network is known in cellular detail 11,14,15. The results drawn from the experiments performed with extracellular recordings, allow already predictions for mathematical models and for roboticists.
All swimmeret neurons show dendritic branching within the Lateral Neuropil and can be intracellularly recorded from these dendrites. In Figure 20, an intracellular recording of a PS motor neuron is shown. For this a sharp microelectrode (see supplements) filled with 1 M KAc + 0.1 M KCl (electrode resistance between 35 – 45 MΩ) is placed above the Lateral Neuropil. The oscillating membrane potentials as well spikes from the dendrites of PS and RS motor neurons can be recorded when the electrode is inserted near the base of nerve N1.
To stain individual neurons (e.g., motor neurons) intracellularly as shown in Figure 21, the sharp microelectrode must be additionally filled with fluorescent dye (e.g., 1% dextran Texas Red, see supplements) dissolved in 1 M KAc + 0.1 M KCl. To fill motor neurons intracellularly by iontophoresis, polarizing pulses of 1 nA with a duration of 250 ms at 2 Hz are applied for at least 10 min. For positively charged dyes use depolarizing pulses and for negatively charged dyes use hyperpolarizing pulses. Longer fills result in a stronger labeled neuron. For visualization the nerve cord must be fixed, dehydrated, and mounted 22.
One method to stain a pool of motor neurons is to use backfills from the nerve N1 (Figure 22) 4,23. Place a well of petroleum jelly around the posterior branch of the nerve N1 to backfill the pool of PS motor neurons. To stain the pool of RS motor neurons a well is placed on the anterior branch of the nerve N1. The crayfish saline in the well is replaced by ddH2O. Then cut this nerve inside the well and leave it for 15 min in ddH2O at room temperature (RT). Thereafter, replace the ddH2O in the wells with either 5% CoCl2– or 5% NiCl2– solution (dissolved in ddH2O) and close wells with petroleum jelly. The sample needs to be incubated for at least 15 hr at 4 °C. Open the wells, remove the dye and rinse the sample 3 times with saline. Precipitate the Ni2+or Co2+ ions with 10 drops of Dithiooxamid (saturated solution dissolved in 100% EtOH) for every 10 ml crayfish saline in the Petri-dish, under the hood for 20 min at RT. Ni2+– ions will precipitate to blue Ni(SCH) and Co2+-ions to orange CoS. The nerve cord must be fixed, dehydrated, and mounted in order to acquire images of the labeled cells under a light microscope equipped with a camera.
The authors have nothing to disclose.
We thank Jos Burgert for helping with some of the figures. We are grateful to Ingo Selbach (and the group “Edelkrebsprojekt NRW”) for his efforts to supply the lab with experimental animals. We thank Anna C. Schneider for proofreading first versions of the manuscript. This research was supported by an Emmy Noether DFG grant SM 206/3-1 and a startup grant of the University of Cologne for female faculty.
Name of Material/ Equipment | Tipo | Company | Catalog Number | Comments/ Description |
4-channel extracellular amplifier: MA 102 | Amplifier | Elektroniklabor, Zoologie, Universität zu Köln, Germany | for extracellular recording | |
air-table | Technical Manufacturing Corporation (TMC) a unit of AMETEK Ultra Precision Technologies, Peabody, MA, USA |
63-534 | for intracellular recording | |
Axon Digidata 1440A | Digitizer | Axon Instruments, Molecular Devices Design, Union City, CA | DD1440A | digitizes recorded signals |
big bucket | filled with ice | |||
Clampex & Clampfit | pClamp 10, recording and analysis software | Molecular Devices Design, Union City, CA | pClamps 10 Standard | for extracellular recording |
cold lamp source | with flexible light guide (fiber optic bundle) | Euromex microscopes holland, Arnhem, BD | LE.5211 & LE.5235 | |
computer and monitor | equipped with recording software | for extracellular recording | ||
container and pipette for liquid waste | ||||
crayfish saline | contains (in mM): 5.4 KCl, 2.6 MgCl2, 13.5 CaCl2, and 195 NaCl, buffered with 10mM Tris base and 4.7mM maleic acid; aerated for 3 hours. Adjust at pH of 7.4. | always keep at temperatures ~ 4° C | ||
dextran, Texas Red (3000MW, lysine fixable) | fluorescent dye, lysine fixable | Life Technologies GmbH, Darmstadt, Germany | D3328 | for intracellular dyefill of neurons |
differential pin electrodes | made from stainless steel ɸ 0.2 mm | for extracellular recording | ||
dissection dish | (l x w x h) 15x7x5 cm; linned with black silicone | used in the gross disection | ||
faraday cage | for extracellular recording | |||
fixing pins | for pinning the specimen | |||
forceps (biology, Dumont #5) | Forceps: Biology, tip 0.05 x 0.02 mm, length 11cm, INOX | Fine Science Tools (FST), Germany | 11252-20 | fine forceps: used to pick nerves |
forceps (biology, Dumont #55) | Forceps: Biology, tip 0.05 x 0.02 mm, length 11cm, INOX | Fine Science Tools (FST), Germany | 11255-20 | extra fine forceps: used for desheathing |
forceps (electronic, Dumont #5) | Forceps: Standard, tip 0.1 x 0.06 mm, length 11cm, INOX | Fine Science Tools (FST), Germany | 11251-20 | coarse forceps: used to grab specimen and pins |
intracellular electrode | Borosilicate glass capillaries (outer/inner diameter: 1mm/0.5mm), with filament | Sutter Instruments, Novato, CA | BF100-50-10 | for intracellular recording and dyefill of neurons |
Leica S8 Apo StereoZoom | Dissection Microscope Zoom 1x – 8x | Leica, Germany | 10446298 | for extracellular recording |
microscope table | for extracellular recording | |||
mirror | to illuminate preparation from below | for extracellular recording | ||
modeling clay | for extracellular recording | |||
Olympus SZ61 | Dissection Microscope Zoom 0.67x – 4.5x | Olympus, Germany | for the dissection | |
petri dish | 94 x 16 mm; lined with clear silicone | Greiner bio-one, Germany | 633180 | used to pin the isolated chain of ganglia |
ring scissors | ThoughCut, cutting edge: sharp/blunt, straight: 13cm | Fine Science Tools (FST), Germany | 14054-13 | for gross dissection (steps 2.1 – 2.11) |
saline dispenser with a 16 gauge needle (outer ɸ 1.6mm) attached via a flexible tube. | Volume ~ 60ml, | used for exsanguination | ||
spring scissors or alternative: Vannas spring scissors | cutting edge: 8 mm, tip diameter: 0.2mm, straight: 10cm or cutting edge 2.5 mm, tip diameter 0.075 mm, straight: 8cm | Fine Science Tools (FST), Germany | 15024-10 or 15000-08 | for desheathing |
stainless steel wire ɸ 0.125 mm | to cut pins of 4-7 mm length | Goodfellow GmbH, Bad Nauheim, Germany | for pinning of the nerve cord | |
student Vannas spring scissors or alternative: Moria Spring Scissors | cutting edge: 5mm, tip diameter: 0.35mm, straight: 9cm or cutting edge: 5mm, tip diameter 0,1 mm, straight: 8 cm | Fine Science Tools (FST), Germany | 91500-09 or 15396-00 | for gross and fine disection (steps 2.11 – 3.14) |
sylgard | 184 Silicone Elastomer Base and Curing Agent; for black sylgard add activated carbon | Dow Corning, Midland, MI, USA | ||
syringe filled with petroleum jelly and equipped with a 20 gauche needle with rounded tip | for extracellular recording |