Tag: heterotroph

On eating plants.

On eating plants.

In the mid-1800s, Claude Bernard – the “father of experimental physiology” – began a series of experiments to create carnivorous rabbits.

Don’t worry: Bernard wasn’t cultivating predatory beasts like the angry rabbit in Monty Python and the Holy Grail. At first he was simply starving animals until their acidic urine indicated that they’d begun to consume their own flesh as fuel. Deprived of calories, any animal will metabolize its own muscle.

But Bernard went further. As he describes in An Introduction to the Study of Experimental Medicine (translated by Henry Copley Greene), Bernard felt that:

A carnivorous rabbit had to be experimentally produced by feeding it with meat …”

I had rabbits fed on cold boiled beef (which they eat very nicely when they are given nothing else). My expectation was again verified …”

To complete my experiment, I made an autopsy on my animals, to see if meat was digested in the same way in rabbits as in carnivora. I found, in fact, all the phenomena of an excellent digestion in their intestinal reactions …”

This was a strange experiment. Claude Bernard did make a novel discovery, but I don’t think the gains were commensurate with the cost.

Bernard, however, was proud of his willingness to inflict pain for the sake of science. He had a reputation for live dissections of unanesthetized dogs; his spouse called him a monster, divorced him, and created France’s first animal welfare organization.

By all outward appearances, Bernard was unperturbed. He told his friends and colleagues that he’d only married that woman for her money, anyway, which he’d needed to build his first laboratory. By the time she left, she was of no further use to him. And he was disinterested in her “fashionable” morality.

In An Introduction to the Study of Experimental Medicine, Bernard writes that,

A physiologist is not a man of fashion, he is a man of science, absorbed by the scientific idea which he pursues: he no longer hears the cry of animals, he no longer sees the blood that flows, he sees only his ideas and perceives only organisms concealing problems which he intends to solve.

#

Claude Bernard tortured animals, disdained Charles Darwin’s theory of evolution, and loathed the introduction of statistics into biological research. Still, the conclusion of Bernard’s rabbit experiment is correct.

Herbivores can digest meat.

And this transition – an herbivore switching to a meat-based diet – is far more common than its opposite. Plants are much more difficult to eat!

#

Most species that we think of as herbivores will occasionally eat meat. Cows consume chickens, mice, dead rabbits (especially if the cows are mineral deficient, such as the experimental herds intentionally fed a low-phosphorous diet in the 1990s). Squirrels raid nests to eat baby birds. Pandas will eat roadkill if they can’t find enough bamboo.

After all, another animal’s body provides the full compliment of nutrients that an animal needs – it’s much easier to live as a mere meat refurbisher than to create your own animal body from scratch!

#

In a research article published in 2019, “Evolution of Diet Across the Animal Tree of Life,” Christian Roman-Palaclos, Joshua Scholl, and John Wiens speculate that the very first animals were carnivores. They write that:

Remarkably, our results suggest that many carnivorous animals alive today may trace this diet through a continuous series of carnivorous ancestors stretching back for >800 million years.”

Their data don’t actually support this claim. Roman-Palaclos, Scholl, and Wiens categorized the diets (herbivorous, carnivorous, or omnivorous) of a wide range of animal species and found that a statistical model in which the first multicellular animals consumed other heterotrophs would be mathematically parsimonious. Historically, it would take fewer genetic changes to produce our world if herbivory had evolved independently many times over.

But evolution tends to be quite rapid when organisms encounter an empty ecological niche, which is why we see sudden increases in diversity during periods following mass extinctions (like the “Cambrian explosion”) and when animals reach new islands. And we know that multicellular life arose multiple times – at the very least, happening independently in both plants and animals.

The earliest multicellular animals were probably simple aggregates of cells that failed to separate after dividing. Even after genes could cause intentional multicellular development, these early animals were probably blobby things that pursued the same diets as their single-celled precursors.

All told, many of the assumptions made by Roman-Palaclos, Scholl, and Wiens seem dubious at best.

And yet. It probably would have been easier for earliest animals to eat other heterotrophs than to eat autotrophs. Single-celled protists already liked to eat the autotrophs, so most autotrophs had defenses. The autotrophs might be toxic; their tasty molecules were hidden behind indigestible cell walls. If the first multicellular animal gobbled these up, it would’ve gotten such a bellyache!

Except, right. The first multicellular animal didn’t have a belly.

It would’ve gotten such a lysosome-ache!!

#

In more recent evolution, herbivorous mammals often developed pretty major adaptations to accompany their diet. For instance, herbivores typically have more complicated teeth than carnivores – by chewing their food, herbivores can rupture a plant’s cell walls to access the nutrients inside. And instead of stealing a full compliment of essential amino acids and vitamins from another animal, an herbivore has to synthesize these inside its body. Biosynthesis of Vitamin B12 is pretty tricky – my cells certainly can’t do it. Can yours?

A human whose body contained only human cells could barely digest anything, and certainly not plants. Indeed, most human babies begin life this way – as wholly human. Newborns seem to have very few bacteria inside their bodies, and it’s difficult for newborns to digest anything other than milk.

Soon after birth, though, humans acquire a wide range of passengers. On the surface of our skin and throughout our intestines, we harbor bacteria, many of which are essential for our health. Our passengers interact directly with our brains: certain gut microbes make exercise more pleasurable; other gut microbes are so closely linked with mood & mental wellness that researchers are exploring ways to use them therapeutically.

Without the help of the bacteria who build empires inside our bodies, we would be miserable – achy, asthmatic, bloated, and mentally unsound. And also, yes – without their help, we could not eat plants.

How fortunate that we are not alone!

Header image credit: Darryl Leja for the National Human Genome Research Institute’s photostream on flickr.

On the ethics of eating.

On the ethics of eating.

Every living thing needs energy.  But our world is finite.  Energy has to come from somewhere.

Luckily, there’s a lot of potential energy out there in the universe.  For instance, mass can be converted into energy.  Our sun showers us with energy drawn from the cascade of nuclear explosions that transpire in its core. A tiny difference in mass between merging hydrogen atoms and the resultant helium atom allows our sun to shine.

Our sun radiates about 10^26 joules per second (which is 100,000 times more than the combined yearly energy usage from everyone on Earth), but only a fraction of that reaches our planet.  Photons radiate outward from our sun in all directions, so our planet intercepts only a small sliver of the beam.  Everything living here is fueled by those photons.

When living things use the sun’s energy, we create order – a tree converts disordered air into rigid trunk, a mouse converts a pile of seeds into more mouse, a human might convert mud and straw into a house.  As we create order, we give off heat.  Warming the air, we radiate infrared photons.  That’s what night vision goggles are designed to see.  The net effect is that the Earth absorbs high-energy photons that were traveling in a straight beam outward from the sun … and we convert those photons into a larger number of low-energy photons that fly off every which way.

Image by Dr.Marek Roland on Wikimedia Commons.

We the living are chaos machines.  We make the universe messier.  Indeed, that’s the only way anything can live.  According to the Second Law of Thermodynamics, the only processes that are sufficiently probable so as to occur are those that make the world more random.

We’re lucky that the universe started out as such a bland, orderly place – otherwise we might not even be able to tell “before” from “later,” let alone extract enough energy to live.

Dog!

The earliest living things took energy from the sun indirectly – they used heat, and so they were fueled by each photon’s delivery of warmth to the Earth.  (Please allow me this little hedge – although it’s true that the earliest life was fueled only by warmth, that warmth might not have come from the sun.  Even today, some thermophilic bacteria live in deep sea vents and bask in the energy that leaks from our Earth’s molten core.  The earliest life might have lived in similar nooks far from the surface of the Earth.  But early life that resided near the surface of the seas seems more likely. Complicated chemical reactions were necessary to form molecules like RNA.  Nucleic acids were probably first found in shallow, murky pools pulsed with lightning or ultraviolet radiation.)

Over time, life changed.  Organisms create copies of themselves through chemical processes that have imperfect fidelity, after all.  Each copy is slightly different than the original.  Most differences make an organism worse than its forebears, but, sometimes, through sheer chance, an organism might be better at surviving or at creating new copies of itself.

When that happens, the new version will become more common. 

Over many, many generations, this process can make organisms very different from their forebears.  When a genome is copied prior to cell division, sometimes the polymerase will slip up and duplicate a stretch of code.  These duplication events are incredibly important for evolution – usually, the instructions for proteins can’t drift too far because any change might eliminate essential functions for that cell.  If there’s a second copy, though, the duplicate can mutate and eventually gain some new function.

Image by Smedlib on Wikimedia Commons.

About two billion years ago, some organisms developed a rudimentary form of photosynthesis.  They could turn sunlight into self!  The energy from our sun’s photons was used to combine carbon dioxide and water into sugar. And sugar can be used to store energy, and to build new types of structures.

Photosynthesis also releases oxygen as a biproduct.  From the perspective of the organisms living then, photosynthesis poisoned the entire atmosphere – a sudden rise in our atmosphere’s oxygen concentration caused many species to go extinct.  But we humans never could have come about without all that oxygen.

Perhaps that’s a small consolation, given that major corporations are currently poisoning our atmosphere with carbon dioxide.  Huge numbers of species might go extinct – including, possibly, ourselves – but something else would have a chance to live here after we have passed.

In addition to poisoning the atmosphere, photosynthesis introduced a new form of competition.  Warmth spreads diffusely – on the early Earth, it was often sheer chance whether one organism would have an advantage over any other.  If you can photosynthesize, though, you want to be the highest organism around.  If you’re closer to the sun, you get the first chance to nab incoming photons.

That’s the evolutionary pressure that induced plants to evolve.  Plants combined sugars into rigid structures so that they could grow upwards.  Height helps when your main goal in life is to snatch sunlight.

Animation by At09kg on Wikipedia.

Nothing can live without curtailing the chances of other living things.  Whenever a plant absorbs a photon, it reduces the energy available for other plants growing below.

Plants created the soil by trapping dirt and dust, and soil lets them store water for later use.  But there is only so much desalinated water.  Roots reach outward: “I drink your milkshake!”, each could exclaim.

For a heterotroph, the brutality of our world is even more clear.  Our kind – including amoebas, fungi, and all animals – can only survive by eating others.  We are carbon recyclers.  Sugar and protein refurbishers.  We take the molecular machines made by photosynthesizing organisms … chop them apart … and use the pieces to create ourselves.

Some heterotrophs are saprophages – eaters of the dead.  But most survive only by destroying the lives of others.

Image by Mikael Häggström on Wikimedia Commons, using originals by Laghi lBorgQueenBenjah-bmm27RkitkoBobisbobJacek FHLaghi L and Jynto.

For the earliest heterotrophs, to eat was to kill.  But, why worry?  Why, after all, is life special?  Each photosynthesizing organism was already churning through our universe’s finite quantity of order in its attempt to grow.  They took in material from their environment and rearranged it.  So did the heterotrophs – they ingested and rearranged. Like all living things, they consumed order and excreted chaos.

The heterotrophs were extinguishing life, but life is just a pattern that repeats itself.  A living thing is a metabolic machine that self-copies.  From a thermodynamic perspective, only the energetics of the process distinguish life from a crystal.  Both are patterns that grow, but when a crystal grows, it makes matter more stable than its environment – life makes matter less stable as it’s incorporated into the pattern.

Your ability to read this essay is a legacy of the heterotrophs’ more violent descendants.  The earliest multicellular heterotrophs were filter feeders – they passively consumed whatever came near.

But then, between 500 and 600 million years ago, animals began to hunt and kill.  They would actively seek life to extinguish.  To do this, they needed to think – neurons first arose among these hunters.

Not coincidentally, this is also the time that animals first developed hard shells, sharp spines, armored plates – defenses to stop others from eating them.

The rigid molecules that allow plants to grow tall, like cellulose, are hard to digest.  So the earliest hunters probably began by killing other animals.

With every meal, you join the long legacy of animals that survived only by extinguishing the lives of others.  With every thought, you draw upon the legacy of our forebear’s ruthless hunt.

Even if you’re vegan, your meals kill.  Like us, plants have goals.  It’s a matter of controversy whether they can perceive – perhaps they don’t know that they have goals – but plants will constantly strive to grow, to collect sunlight and water while they can, and many will actively resist being eaten.

But it makes no sense to value the world if you don’t value yourself.  Maybe you feel sad that you can’t photosynthesize … maybe you’d search out a patch of barren, rocky ground so that you’d absorb only photons that would otherwise be “wasted” … but, in this lifetime, you have to eat.  Otherwise you’d die.  And I personally think that any moral philosophy that advocates suicide is untenable.  That’s a major flaw with utilitarianism – rigid devotion to the idea of maximizing happiness for all would suggest that you, as another organism that’s taking up space, constantly killing, and sapping our universe’s limited supply of order, simply shouldn’t be here.

At its illogical extreme, utilitarianism suggests that either you conquer the world (if you’re the best at feeling happy) or kill yourself (if you’re not).

We humans are descended from carnivores.  Our ancestors were able to maintain such large brains only by cooking and eating meat.  Our bodies lack an herbivore’s compliment of enzymes that would allow us to convert grass and leaves into the full compliment of proteins that we need.

And we owe the very existence of our brains to the hunts carried out by even more ancient ancestors.  If they hadn’t killed, we couldn’t think.

Just because we were blessed by a legacy of violence, though, doesn’t mean we have to perpetuate that violence.  We can benefit from past harms and resolve to harm less in the present and future.

Writing was first developed by professional scribes.  Scientific progress was the province of wealthy artisans.  None of the progress of our culture would have been possible if huge numbers of people weren’t oppressed – food that those people grew was taken from them and distributed by kings to a small number of privileged scribes, artisans, philosophers, and layabouts. 

When humans lived as hunters and gatherers, their societies were generally equitable.  People might die young from bacterial infections, dehydration, or starvation, but their lives were probably much better than the lives of the earliest farmers.  After we discovered agriculture, our diets became less varied and our lives less interesting.  Plus, it’s easier to oppress a land-bound farmer than a nomadic hunter.  Stationary people paid tribute to self-appointed kings.

This misery befell the vast majority of our world’s population, and persisted for thousands of years.  But the world we have now couldn’t have come about any other way.  It’s horrific, but, for humans to reach our current technologies, we needed oppression.  Food was taken from those who toiled and given to those who hadn’t. 

Mostly those others created nothing of value … but some of them made writing, and mathematics, and rocket ships.

Although the development of writing required oppression, it’s wrong to oppress people now.  It was wrong then, too … but we can’t go back and fix things.

Although the origin of your brain required violence, I likewise think we ought to minimize the violence we enact today.  We can’t help all the animals who were hurt in the long journey that made our world the place it is now.  And we can’t stop killing – there’s no other way for heterotrophs like us to live.

To be vegan, though, is to reckon with those costs.  To feel a sense of wonder at all the world pays for us to be here.  And, in gratitude, to refrain from asking that it pay more than we need.

On violence and gratitude.

On violence and gratitude.

Although I consider myself a benevolent tyrant, some of my cells have turned against me.  Mutinous, they were swayed by the propaganda of a virus and started churning out capsids rather than helping me type this essay.  Which leaves me sitting at a YMCA snack room table snerking, goo leaking down my throat and out my nose.

Unconsciously, I take violent reprisal against the traitors.  I send my enforcers to put down the revolt – they cannibalize the still-living rebels, first gnawing the skin, then devouring the organs that come spilling out.  Then the defector dies.

800px-CD8+_T_cell_destruction_of_infected_cells
CD8+ T cell destruction of infected cells by Dananguyen on Wikimedia.

My cells are also expected to commit suicide whenever they cease to be useful for my grand designs.  Any time a revolutionary loses the resolve to commit suicide, my enforcers put it down.  Unless my internal surveillance state fails to notice in time – the other name for a cell that doesn’t want to commit suicide is “cancer,” and even the most robust immune system might be stymied by cancer when the traitor’s family grows too large.

Worse is when the rebels “metastasize,” like contemporary terrorists.  This word signifies that the family has sent sleeper agents to infiltrate the world at large, attempting to develop new pockets of resistance in other areas.  Even if my enforcers crush one cluster of rebellion, others could flourish unchecked.

800px-How_metastasis_occurs_illustration
How metastasis occurs. Image by the National Cancer Institute on Wikimedia.

I know something that perhaps they don’t – if their rebellion succeeds, they will die.  A flourishing cancer sequesters so many resources that the rest of my body would soon prove too weak to seek food and water, causing every cell inside of me to die.

But perhaps they’ve learned my kingdom’s vile secret – rebel or not, they will die.  As with any hereditary monarchy, a select few of my cells are privileged above all others.  And it’s not the cells in my brain that rule.

Every “somatic cell” is doomed.  These cells compose my brain and body.  Each has slight variations from “my” genome – every round of cell division introduces random mutations, making every cell’s DNA slightly different from its neighbors’.

The basic idea behind Richard Dawkins’s The Selfish Gene is that each of these cells “wants” for its genome to pass down through the ages.  Dawkins argued that familial altruism is rational because any sacrifice bolsters the chances for a very similar genome to propagate.  Similarly, each somatic cell is expected to sacrifice itself to boost the odds for a very similar genome carried by the gametes.

Only gametes – the heralded population of germ cells in our genitalia – can possibly see their lineage continue.  All others are like the commoners who (perhaps foolishly) chant their king or kingdom’s name as they rush into battle to die.  I expect them to show absolute fealty to me, their tyrant.  Apoptosis – uncomplaining suicide – was required of many before I was even born, like when cells forming the webbing between my fingers slit their own bellies in dramatic synchronized hara-kiri.

28407608404_84b3c64433_h
Human gametes by Karl-Ludwig Poggemann on Flickr.

Any evolutionary biologist could explain that each such act of sacrifice was in a cell’s mathematical best interest.  But if I were a conscious somatic cell, would I submit so easily?  Or do I owe some sliver of respect to the traitors inside me?

The world is a violent place.  I’m an extremely liberal vegan environmentalist – yet it takes a lot of violence to keep me going.

From Suzana Herculano-Houzel’s The Human Advantage:

image (1)Animals that we are, we must face, every single day of our lives, the consequences of our most basic predicament: we don’t do photosynthesis.  For lack of the necessary genes, we don’t just absorb carbon from the air around us and fix it as new bodily matter with a little help from sunlight.  To survive, we animals have to eat other living organisms, whether animal, vegetable, or fungus, and transform their matter into ours.

And yet the violence doesn’t begin with animals.  Photosynthesis seems benign by comparison – all you’d need is light from the sun! – unless you watch a time-lapsed video of plant growth in any forest or jungle.

The sun casts off electromagnetic radiation without a care in the world, but the amount of useful light reaching any particular spot on earth is limited.  And plants will fight for it.  They race upwards, a sprint that we sometimes fail to notice only because they’ve adapted a timescale of days, years, and centuries rather than our seconds, hours, and years.  They reach over competitors’ heads, attempting to grab any extra smidgen of light … and starving those below.  Many vines physically strangle their foes.  Several trees excrete poison from their roots.  Why win fair if you don’t have to?  A banquet of warm sunlight awaits the tallest plant left standing.

And so why, in such a violent world, would it be worthwhile to be vegan?  After all, nothing wants to be eaten.  Sure, a plant wants for animals to eat its fruit – fruits and animals co-evolved in a system of gift exchange.  The plant freely offers fruit, with no way of guaranteeing recompense, in hope that the animal might plant its seeds in a useful location.

But actual pieces of fruit – the individual cells composing an apple – probably don’t want to be eaten, no more than cancers or my own virus-infected cells want to be put down for the greater good.

A kale plant doesn’t want for me to tear off its leaves and dice them for my morning ramen.

But by acknowledging how much sacrifice it takes to allow for us to be typing or reading or otherwise reaping the pleasures of existence, I think it’s easier to maintain awe.  A sense of gratitude toward all that we’ve been given.  Most humans appreciate things more when we think they cost more.

We should appreciate the chance to be alive.  It costs an absurd amount for us to be here.

But, in the modern world, it’s possible to have a wonderful, rampantly hedonistic life as a vegan.  Why make our existence cost more when we don’t have to?  A bottle of wine tastes better when we’re told that it’s $45-dollar and not $5-dollar wine, but it won’t taste any better if you tell somebody “It’s $45-dollar wine, but you’ll have to pay $90 for it.”

Personally, I’d think it tasted worse, each sip with the savor of squander.