EXPLOIT 🚨 FLOWERING LOCUS T (FT) 🚨
Impact
CRITICAL
Detection Date 2025-01-22
Investigation Supercannabis Legion 🇦🇷
If we consider that phytochrome takes
13 hours to deactivate
to induce flowering,
but the protein
FLOWERING LOCUS T (FT)
keeps floral hormones
active for nearly 30 hours then we could exploit a
BIOLOGICAL BUFFER OVERFLOW
HOW WOULD THE BUFFER OVERFLOW WORK IN THE
FT-Exploit
Cannabis is a short-day plant.
Its flowering is controlled by the activation of
phytochrome,
a photoreceptor protein that regulates the transition between vegetative growth and flowering.
Under natural conditions
Phytochrome takes approximately 13 hours of darkness to fully deactivate
, allowing the plant to initiate the flowering process.
From that event (13 hours of darkness), floral hormones regulated by the
FLOWERING LOCUS T (FT)
remain active for up to
30 hours
The problem is that traditional cycles
do not fully leverage this hormonal dynamic
optimally.
INDOOR CULTIVATION FOLLOWS A 24-HOUR CYCLE, CREATING DEAD TIME IN HORMONAL ACTIVATION AND WASTING PRODUCTION POTENTIAL.
🧪 THE PHYTOCHROME MECHANISM AND ITS IMPACT ON FLOWERING 🧪
Phytochrome is a light control system composed of two interconvertible states.
RED PHYTOCHROME (Pr)
It is the inactive form and absorbs red light (~660 nm).
It converts into
far-red phytochrome (Pfr)
upon receiving red light, promoting photosynthetic activity and vegetative growth.
FAR-RED PHYTOCHROME (Pfr)
It is the active form and accumulates during the daytime photoperiod.
In darkness, it slowly degrades into
PR
, a process necessary to activate the
FT production
and maintain flowering.
HERE IS THE VULNERABILITY OF THE TRADITIONAL SYSTEM OF 24 HOURS
If the darkness period is less than 13 hours, Pfr does not fully degrade, preventing proper flowering activation.
If light is interrupted before the 30-hour FT activation, flowering could remain active without needing to complete conventional light/dark cycles.
This discovery led us to the design of
SuperCycle
, a way to manipulate activation and deactivation times to
maximize flowering without losing photosynthetic efficiency.
BIOLOGICAL BUFFER OVERFLOW
THE ULTIMATE EXPLOIT
If phytochrome needs
13 hours of darkness
to enable flowering, but
FLOWERING LOCUS T (FT)
keeps floral activation going for
30 hours
we are facing an opportunity to
HACK
the cannabis flowering cycle.
How the FT-EXPLOIT Works
IF (FT) REMAINS ACTIVE FOR 30 HOURS, WE COULD EXTEND LIGHT UP TO THIS LIMIT WITHOUT INTERRUPTING FLOWERING, THEN RESET IT WITH 13/14 HOURS OF DARKNESS AND RESTART
During these 30 hours of light, phytochrome would remain partially activated but without disrupting floral hormonal regulation.
If we continue extending the light cycle without providing sufficient darkness,
we could induce prolonged flowering
without interruptions.
In theory, we could keep the plant in continuous flowering
without reverting to the vegetative state,
which would mean a massive increase in production without altering its natural biology.
This approach
challenges traditional photoperiods
that are based on
outdated biological time models.
FT's hormonal buffer would allow us to exploit longer light cycles without affecting flowering quality.
Further testing in different genetics is required to confirm the final impact,
but this finding suggests a
new frontier in optimizing indoor cultivation.
PROOF OF CONCEPT FLOWERING EVIDENCE
Supercycle is currently being successfully tested
FLOWERING DAY 31 SUPERCYCLE
17 LIGHT / 13 DARKNESS
We are not simply adding more light or more darkness.
WE ARE REWRITING THE RULES OF THE PHOTOPERIOD TO OPTIMIZE FLORAL GROWTH IN THE MOST EFFICIENT WAY POSSIBLE
URGENT RECOMMENDATION UPDATE YOUR GROW NOW
If you are still using
12/12 or 13/11
you are losing production
and flowering quality.
Supercycle + FT-Exploit
are the ultimate optimization of the photoperiod.
From Argentina to the world, we are revolutionizing indoor cultivation.
HACKERS UNITED WE ARE EVOLUTION
Now it's your turn to choose your own adventure
Do you want to start testing some of the Supercycles and share what results you can achieve?
Or maybe you prefer to know what we are trying to discover with this research.
Who knows, maybe you can help us find the best supercycle!
