Nov 292013
 

As I was saying, we vertebrates tend to have a high opinion of the big clump of neurons that sits at one end of our spinal cord.  And so we should: in creatures like us, that’s where the magic happens.  The bigger the clump, the more cognitively versatile the organism; remove it, and the whole organism comes to a stop (though it may run around for a while, first).

But, as we know, even unicellular beings are capable of sensation and coordinated movement, and can show complex, even purposeful, behaviours.  So, it was probably inevitable that some well-meaning scientist would try to equip them with a central nervous system of their own.

Stylonychia crawling Actinophrys

Stylonychia mytilus crawling on a filament of algae. Image by Actinophrys, on Flickr. Click for Link.

In 1880, a German researcher named Th. W. Engelmann undertook a close inspection of the tissues of the ciliate Stylonychia mytilus.  Like other members of the ciliate group loosely known as “hypotrichs,” Stylonychia has, on its “belly,” a crop of thick, mobile cirri: bundles of fused cilia that it uses like little legs, as it scrambles around on solid objects in its sunken world.  These pseudo-legs work very well, and a crawling hypotrich can look a lot like a beetle or cockroach.

Unlike the limbs of insects, the cirri of hypotrichs lack conspicuous attachments, such as muscles, tendons and nerves. However, looking very closely at stained samples, Engelmann was able to detect, at the bases of Stylonychia’s cirri, groups of fibres which he called “Wimperwurzeln,” or “ciliary rootlets.” These fibres, he speculated, might just function as nerves do in “higher” organisms, serving as the conductive tracks along which the stimuli that move the cilia might move!

It was an innovative idea; however, it did not spark much excitement. Despite his impressively clear record of these small structures, the suggestion that he had discovered animal-like organs in unicellular creatures might have come at the wrong time. By 1880, the view of protozoa as miniature animals, bearing a complete set of reproductive and alimentary organs, had been discredited a long time before. In the late 19th century, protozoa were conventionally seen as primitive organisms, little more than bags of the all-purpose protoplasm that constituted, in Thomas Huxley’s memorable phrase, the “physical basis of life.”

But times change, and the idea that free-living cells might be composed of differentiated tissues would came back into style (in fact, in the early 20th century some protozoologists completely rejected the cellular nature of their organisms).

Charles Kofoid picture

Charles Atwood Kofoid

In 1914, Robert G. Sharp–working in California under the guidance of the eminent protozoologist Charles Atwood Kofoid–published a paper in which he boldly claimed to have found a ciliate that not only had nerve-fibres, but a full-blown centrally located “neuromotor apparatus.” He discovered this structure in an organism called Diplodinium ecaudatum (now known as Epidinium ecaudatum), a symbiont in the stomachs of cattle. What Sharp found had never been recorded anywhere: a small mass of fibres close to the cell’s motile organelles, and serving as “the common center of motor influences.” He had discovered the organ that controlled and coordinated the moving parts of the ciliate, in effect, the cytoplasmic “brain” of the cell. He called this the “motorium.”

Sharp’s paper kicked up a little whirlwind of scientific activity, particularly among his colleagues at Kofoid’s laboratory. The following year, Kofoid himself described a “neuromotor apparatus” in the intestinal parasite, Giardia. Shortly after, Harry B. Yocom, another worker in Kofoid’s group, published the discovery of a full-blown neuromotorium in the hypotrich Euplotes patella (a “walking ciliate” like Stylonychia).

But why ascribe a neural function to the structures he saw in Euplotes? Yocom goes into some detail about that. In the first place, these fibres turn a vivid red in the fuchsin from Mallory’s stain, just as nerve cells do in metazoa; in the second place, he explains, these fibres are found in association with the moving parts of the ciliate: the oral membranelles and the locomotory cirri.

Yocom Euplotes neuromotor apparatus circled in red

Yocom’s illustration of the neuromotor apparatus in Euplotes patella, with the “motorium” circled in red.

Finally, the behaviour of Euplotes patella appeared to support this interpretation. It is, perhaps, a classic example of hypothesis leading observation by the nose. To Yocom, it seemed evident that E. patella was using its “anterior lip” (the bulge at the top of the cell, which showed a red-staining lattice of fibres) as a sensory organ. What’s more, the transverse cirri, which were linked to the “motorium,” moved in a coordinated way, while the unattached cirri moved randomly.  As Yocom puts it: “[T]he whirling irregular movements of the frontal ventral and marginal cirri are in no way coordinated with the regular rhythmical movements of the membranelles or with the backward kick of the cirri.”

Or, so it looked to him.

Up to that point, the function of the “neuromotorium” as a “coordinating center” for the cell’s movements was simply a hypothesis, unsupported by experiment. But confirmation was not long in coming. In 1919, C. V. Taylor–yet another worker from the Berkeley circle–conducted an experiment on Euplotes patella, the ciliate Yocom had studied in such detail the year before. Using quartz microscalpels, he severed the fibres running between the motorium and the anal cirri (the prominent group of five heavy cirri in the posterior half of the cell, now usually known as “transverse cirri”). The experiment resoundingly confirmed the hypothesis; detached from the motorium, the cirri did not seem to work properly at all: “Severing the fibers to the anal cirri affects both creeping and swimming…Destroying the motorium or cutting its attached fibers interrupts coordination in the movements of the adoral membranelles and anal cirri.”  (Taylor, 1919)

Paramecium nerve center with red circle

Paramecium from Rees (1920), showing a tracery of fine “neurofibrils” (skeletal microtubules, presumably) converging on the “nerve center” of the cell, circled here in red.

From then on, the neuromotor apparatus turned up in one ciliate after another. It was found in Paramecium (1920), Balantidium (1922), Tintinnopsis (1926), Dileptus (1927), Chlamydodon (1928), Uroleptus (1930), and Oxytricha (1935). Along the way, doubt steadily faded, and by 1927 it was possible to affirm plainly that “a complicated neuromotor system has been conclusively demonstrated to exist in certain ciliated infusoria.” (Visscher, 1927) It had become, in North America, at least, a solid fact.

But even solid facts can turn fluid again, and then evaporate like the canals of Mars.  It can happen slowly, or all at once.  Sometimes a hypothesis dies a quick death, when an experiment disproves it; sometimes it is swept off in the riptide of a better theory; and sometimes it just get nibbled away, while the world slowly changes around it, until one day nobody can remember why it had ever seemed true.

The neuromotor concept had a long run, outlasting Kofoid himself by a decade and a half.  Even the advent of electron microscopy did not kill it off, right away.  As late as 1957, EM seemed to reveal in Euplotes “a mass of intertwining rootlet filaments” corresponding to the neuromotorium, as well as a whole system of intracellular fibres which were mainly dedicated, as the authors argued, to “the coordination of the ciliary beat.” (Roth, 1957) But when R. Gliddon again placed Euplotes under the electron microscope, in 1966, he could not find anything you could call a motorium.  It had disappeared.

In that same year, two researchers in Japan finally got around to replicating Taylor’s classic experiment on E. patella–the experiment that, arguably, had kicked off the neuromotorium gold rush. (Okajima and Kinosita, 1966) But now, the results were very different.  The investigators severed the “neurofibrils,” just as Taylor had done, and captured the ciliary movements on film; however, this time the cirri just kept on moving in their usual coordinated way, as if nothing had happened. It is not known why Taylor’s Euplotes had behaved differently.  Possibly, he mangled the poor things while dissecting their “neurofibrils” and made his celebrated observations on organisms in their death throes.

In 1970, Dorothy Pitelka was ready to call the game, announcing the general “abandonment of the old concept of a fibrillar neuromotor system in ciliates.” A casual search in Google Books turns up one last, brief reference to the “neural fibrils” of Paramecium, in a high school biology textbook published in 1983.  After that, nothing.

So what were the “neurofibrils,” in the end? They were not a product of poor equipment or fanciful observation, but rather the opposite. Remarkably, it seems that microscopists of the day were already detecting parts of the cytoskeleton–the scaffolding of microtubules and filaments that give the cell its shape–as well as the pellicular “latticework,” the so-called ciliate “silverline system” which would later be fully exposed in silver nitrate and protargol preparations. Interpretation lagged behind observation for a generation or two. Seeing had outstripped understanding; then new information came, and the old certainties just sank back into the pondwater.

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Nov 232013
 

When René Descartes searched through the human brain to find the Seat of the Soul, he settled on the pineal gland, a small endocrine organ found in nearly all vertebrates. It seemed like a good candidate, because it is a singular organ, not duplicated on each half of the brain but perched right on the midline, where it could, as Descartes imagined, receive sensory impressions through little pipes, and flex the muscles of the body by exhaling “animal spirits” along a system of hoses leading to the arms and legs.

Descartes brain 4b

Illustration from Traité de l’Homme (1644), showing the teardrop-shaped pineal gland perched in the skull like a little Mecha-pilot.

Descartes’ soul sits at the control centre of the meat-puppet, gathering news of the world through its eyes, ears and nose and exerting its will upon the world through the pneumatic machinery of the body.

It is easy to recognize in his conception a structure analogous to  what we know as the nervous system. We no longer think in terms of “animal spirits,” but rather of “neural signals,” and we no longer place the mind within any particular gland in the brain. But for most of us, who have only a rough understanding of how it all works, this “signal/transmitter/receiver” scheme is only another metaphor, just a little more sophisticated than the one Descartes used. By and large, we are still operating with the notion of an insubstantial mind somehow localized within a “central” nervous system, conducting its business with the world through an extensive network of  bodily filaments.

Indeed, many of us find it hard to even conceive of an intelligence which is not concentrated  at the top of a hierarchy, running from the brain (where the cogitating self resides) to the tips of the peripheral nerves, where the world lies waiting to be felt, heard and seen.

So, the distributed intelligence of the octopus nervous system–half of its neurons are in its arms!--strikes us as something bizarre and wondrous, requiring further exploration and explanation. Challenging the naive expectation that cognitive processing should be “central” and the organs of sensation “peripheral,” the octopus researchers have devised ingenious experiments to show that the arms of the mollusc continue to perform goal-oriented behaviours, like prey-seeking, exploration and danger-avoidance even when they are severed from the so-called brain.

And if it seems marvelous that a detached octopus arm can still sense and react  to perceived danger, how much weirder is it that a single cell can do all these things, without the benefit of any nervous system at all? But this is perfectly commonplace in the protist world, where one-celled hunters swim around, stalking one-celled victims, who recoil when they sense trouble, take shelter in their shells, or hide from their enemies in clumps of debris.

Just imagine if a single cell of your body could cut loose and go wandering about under its own power like that, hunting and consuming prey! Oh, right…they do. In fact, it is perfectly ordinary for eukaryote cells, whether they are inside larger organisms or roaming at large in the “world,” to exhibit complex behaviours that may be remarkably hard to distinguish from the kinds of behaviours we observe in large, multicellular animals.

Take a ciliate like Stichotricha aculeata. It usually inhabits a shabby, homemade tubular dwelling (a lorica), made up of mucus mingled with debris. It lives by brushing smaller organisms — bacteria and some of the daintier protists — into a mouthlike aperture, where they are packed up in little food-bubbles (vacuoles) and digested. Like a cat or a crayfish, it is both large enough to be a predator, and small enough to be prey. Consequently, it is a cautious creature, relying on its lorica for protection. When it senses trouble, it withdraws into its tube, and when the coast is clear it will put out its long feeding apparatus. Like other ciliates, it can sense movement (probably with the help of sensory cilia, which are common in eukaryotic cells), and is easily startled. If you should tap on the microscope stage with your finger, while you are watching it, it will detect the vibrations and pull back.  After hiding for a while in its jelly-tube, it will extend its proboscis, tentatively. If it encounters no more trouble it will begin to feed again.

However, if the disruption is sufficiently violent or prolonged, it may abandon its lorica altogether, as the closely-related Chaetospira does in a video I recorded last year. The Stichotricha in the embedded footage which follows has already fled its original “home,” and taken shelter in a little enclosed space, between the coral-like tubular dwelling of a colonial flagellate called Rhipidodendron huxleyi, and a mucoid colony of some other organism (Spongomonas?). In this makeshift lorica-substitute, it is behaving exactly as it normally does when at home, sliding forward and back, feeding, withdrawing, advancing, always hungry, and always vigilant:

It is easy to see why early microscopists referred to these creatures as “animalcules: “very small animals”. Without a nervous system, ciliates like Stichotricha and Chaetospira exhibit behaviours strikingly reminiscent of a fish lurking in a crevice, or a case-dwelling insect, like the larval caddisfly. If they often remind us of “true” animals, it is well to remind ourselves that, after all, they have a way of life that differs very little that of other cavity-dwelling aquatic creatures, like the ones we might find on a coral reef, or like this larval midge, in the gravel of a freshwater stream: