The Larval Entiote
Hive Bitch
September 30, 2025
When the eggs make contact with your skin, they hatch and burrow into
your flesh, like blowflies or lice. While you sleep, they'll crawl
out and migrate across your body in the fashion of bedbugs, seeking
the best hiding and feeding spots. Ideal for them is access to
your digestive system.
As they grow, each can split apart to multiply, each asexual
generation enhancing the odds that a questing worm arrives at its goal
--- as well as making the infestation that much harder to permanently
root out.
Still, this presents the first major fork in this branching evolution.
What happens if the larvae achieve their goal: migrating to the
digestive system? Or better yet, the eggs were lucky enough to hatch
there in the first place --- perhaps because they'd laced the hosts
food?
They reached the intestines and grow fat there, unconstrained by the
need to move or hide. Here there's much less work to do --- now it
can simply gorge itself on the hosts' food (a theft which encourges
the host to eat more and more) while it only grows longer and thicker.
Eventually, there are enough larvae crowding their guts to bulge the
stomach. But that doesn't mean the growth will stop.
Unchecked, the larvae will continue replicating even after the host
loses strength or ability or willingness to keep feeding. Even after
no more space remains in the gut, they can simply burst outward and
infest the rest of the internal organs. As you might imagine, no host
will survive long with a chest so full of hungry spawn unleashed;
maggotslime drowns their lungs and their ribs burst while the heart is
devoured.
This is the the natural, ideal process of infestion --- the
parasitoid lifecycle.
A special note is to be made of alternatives to the gut. It's the
ideal, but it's not the only place the maggots can take up residence.
The reproductive system can provide refuge --- mainly in cases where
the host has a womb. Advanced manipulation of hormones may even
persuade the body to direct nutrients to the passenger of its own
accord.
This is not the only possible outcome of the maggots arriving in the
digestive system, but before explaining the alternative, it's
illustrative to examine what happens if they cannot achieve this.
So next let's suppose they never make it to the intestines. This
means they must survive by subtly draining blood and fat deposits.
What exactly happens next depends on the host's response.
Most obviously, one may notice the bites, the growing weakness and
fatigue, the inflammed sickness of an immune system expelling
invaders. If one examines oneself carefully, one will notice the
wounds, the blisters --- one might even catch a worm in the midst of
its wriggle-scurry across an exposed stretch of skin, darting to the
cover of a patch of hair.
If the host scratches at the wounds, squishing or tearing out the
larvae, and wipes themselves down, then one creates selection pressure
for larvae to adapt and hide themselves from notice.
Thus, energy will be diverted from just feeding on the host to
camouflage. This already happens on a chemical level --- sucking up
genes and hormones to imitate the chemical signature of one's biology
and hide from the immune system's notice --- and eventually it also
happens on a physiological level.
At an extreme, the worms will eat the host's muscles, biting into
their attachment sites with teeth and tail-spikes, or cutting open
one's vessels and routing one's blood through themselves. Bit by bit,
one's flesh stops being one's own. It still responds to one's nerve
signals --- for now, so long as that aligns with its own agenda.
This is the fusomorphic lifecycle.
But again, this is an adaptation --- it cannot happen if there's no
need for it to happen. You may have seen photos of people with
necrotic wounds that have decayed to the point of having maggots
visible in their cavities. And of course, those awareness campaigns
telling people to check for suspicious lumps wouldn't be necessary if
everyone noticed these things. It is entirely possible, given the
right host in the wrong circumstances, for the infestation to develop
to an advanced stage essentially untreated.
Thus, the maggots may gather themselves into a tumor-nest and extract
nutrients with little if any pretense of mutualism.
Now, easily this scenario mirrors one of the cases we'll discuss later
on, so what's essential for a unique outcome here is that eventually,
this affliction becomes taxing enough that either the host is forced
to finally seek some treatment for it, or the host begins to outright
fail in gathering sufficient nutrients for the parasite.
Importantly, this all must happen before the larvae have finished
gathering the resources needed for their pupal metamorphosis.
As a result, the parasite is finally forced to divert resources from
extraction and growth toward reinvestment in the survival of its host.
This can mean synthesizing hormones like dopamine and adrenaline to
motivate behavior, and it can mean repairing atrophied muscles and
necrotic flesh with the same techniques of replacement-imitation
outlined in the fusomorphic lifecycle.
But this outcome is a bit different. What distinguishes this is that
here, the parasite isn't hiding, nor is it integrating into the hosts'
biology. Rather, it is colonizing it. The parasite has centralized
itself into the tumor nest, and it only extends larva-tendrils into
the the limbs or hormone-signals into the bloodstream as something
more akin to puppetry.
So that's a decent enough name for this: the quasicolonial lifecycle.
But remember that first fork in the road? We didn't finish exploring
the rest of it.
So, imagine the larvae had arrived in the digestive (or reproductive)
systems by migration. This naturally implies that while some can live
out the easy life in the guts, their sisters are still scraping by
outside. What are they doing?
In most cases, the intestinal larvae will pump covert hormonal
messages into the blood, coordinating the colonies elsewhere in the
host. If there are larvae in the gut, these hormones will suppress
the formation of any rival 'tumor-nests' --- which are just pale
imitation of the gut-palace, after all.
This means that remaining larvae will be directed toward fusomorphic
behavior. This can easily transition toward quasicolonial or outright
fusomorphic, especially if the environment demands parasitic
adaptation to survive, or the host makes an effort to get rid of the
infestation. (But I repeat myself.)
Still, unique behavior can emerge in cases where the host is
accomodating and the environment fruitful. This mean balancing on a
knife's edge. The parasite must grow integrated enough into the
hosts' biology to discourage outright parasitoid consumption, yet not
so intertwined as to advance to total assimilation. It remains a
pampered guest --- free to leave at its whim.
This is the ovipositional lifecycle.
Thus defined, these are the four major modes, but the nature of a such
a flexible lifecycle is that possibilities still abound.
A fifth mode, subtlest of all, can be most clearly outlined now that
the last three are defined. Quasicolonialism implies a certain
dominance of the nervous system; fusomorphism implies a total
conversation of all limbs and organs; oviposition implies ultimate
independence from what the body provides.
If those absolutes are not achieved? If the parasite is limited by
the host, if the transformation-conquest reaches a stalemate, if the
larvae grow too used to the shelter and indulgence of the body? One
could almost imagine it the transplant of a new organ, a xenograft.
This is the endosymbiotic lifecycle.
We can continue: what happens if the host is lacking --- in biomass or
in knowledge --- and the parasite would prefer a mulligan? Larvae
simply infest flesh; should they be lucky, they can migrate to a new
host. Luck, or cunning: a host could be molded into vector replete
with larvae and manipulated into infesting others.
But if those victims remain in contact? Fusomorphsis is, at its core,
the weaving of new anatomy --- what might result from larvae able to
freely slither and insinuate between many hosts? (It's there in the
name; fusomorphosis happens because the because the boundaries
between organisms are so easily blurred.)
But we are getting ahead of ourselves.
Now that we've enumerated the different modes, let us finally finally
illustrate the most important difference between them all. Recall how
the parasites have been repeatedly referred to as larvae --- one is
left to wonder, then, about the chrysalis and emergence. Larva must
eventually spin themselves a cocooon.
In the parasitoid lifecycle, the coccoon engulfs the entire corpse (or
agonized corpse-to-be).
In the fusomorphic lifecycle, the cocoon engulfs the host (or perhaps
only one colonized limb at a time).
In the quasicolonial lifecycle, the cocoon only engulfs the tumor-nest
(an ideal time to remove it --- thus the cocoon often attaches near
vital organs).
In the oviposition lifecycle, the coccoon strains against the guts or
womb, but is adapted for the host to lay it.
In short, the entiote is profoundly adaptive. The host may be its
prey to be savored from without, or a mere nest to occupy then
abandon, or an assimilated extension of itself, or its fertile
breeding stock.
Discussion in the ATmosphere