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This Is the Biggest Technological
Breakthrough Since the Computer
Luke Lango
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T
he world has changed a lot over the past 40 years, and most of those
changes have revolved around one important innovation: The computer.
© Source: Vink Fan / Shutterstock.comCells and molecules representing biology stocks.
© Provided by InvestorPlaceCells and molecules representing biology stocks.
Back in the 1980s, the world started to use these little machines called
computers which were profound because you could program them to
theoretically do any task. As these computers became more powerful – and their
underlying code became more robust – humans started to use them to do
everything, from working, to communicating, to playing.
And so, the Computing Revolution went mainstream.
It is no coincidence that all of today’s trillion-dollar companies are, in some way,
computing companies.
Microsoft (MSFT) makes computers. So does Apple (AAPL).
Facebook (FB) builds applications for use on computers. So
does Alphabet (GOOG).
Unsurprisingly, those companies have all turned their early investors into
millionaires.
In short, the computer profoundly changed our lives over the past 40 years, and
the computing companies pioneering those changes have become the world’s
most powerful businesses while their shareholders have become its wealthiest
people.
So why am I telling you all of this?
Well, today, we’re on the cusp of another technological revolution that could be
as big as – if not bigger than – the computing revolution.
In many ways, it is the Computing Revolution 2.0, because it is the computing
revolution of the past 40 years but applied to living things as opposed to
computers.
I’m talking about rewriting the code of life – a much bigger undertaking than
rewriting the code of machines – through an emerging technology field
called Synthetic Biology.
I know. It sounds crazy. But scientifically speaking, a life cell is just like a
computer – it’s a very powerful machine that runs on digital code. The only
difference is that the code of a computer is in ones and zeros, whereas the
“code” of a life cell is in Gs, Cs, As, and Ts – or the four nucleobases in the
nucleic acid of DNA.
So, in theory, we can manipulate the code of life by changing the order of those
Gs, Cs, As, and Ts. In so doing, we can “code” living things much in the same
way we can “code” inanimate objects, like phones, computers, and cars.
That’s what synthetic biology is all about: Programming life cells like we
program computers, by changing the DNA code inside them.
In practice, it means we can manipulate the code of crops so that they’re pestresistant, or the code of plants so that they’re weather-tolerant. We can
manipulate the code of cancer patients to get rid of their cancer. We can
manipulate the code of yeast to produce better-tasting beer.
The applications are endless.
But, until recently, the emerging field of synthetic biology has been nothing more
than a concept. That’s because rewriting the code of life, as you can imagine, is
quite complex. The human body is a wonder – it is infinitely more complex than a
computer. Each human has a different “code”. And each living specimen – a
plant, a crop, a fish – has a different “code” than humans.
To read all those different codes, you need to employ advanced DNA sequencing
methods, which are among the most complex scientific methods in the world.
Then, to rewrite those codes, you need to use DNA synthesis or printing – which
are so complex that they make sequencing look like child’s play.
Long story short, the universe of synthetic biology is magnitudes more infinite
and complex than the universe of classical computing. So, whereas we’ve made
huge advancements in programming computers over the 40 years, we’ve made
very little progress in programming life cells.
Until now. Recent advancements in artificial intelligence have speed up the DNA
sequencing process, while advancements in classical computing technologies
have improved the accuracy of DNA synthesis and printing. This combination has
– for the first time ever – enabled synthetic biology to work in the real world.
Right now, as we speak, food companies are leveraging synthetic biology to
create pest-resistant crops, beer companies are using synthetic biology to create
higher-yielding yeast, and biotech companies are using synthetic biology to make
new vaccines and medicines.
So begins the Synthetic Biology revolution, or, the biggest technological
paradigm shift since the advent of the computer.
It’s a critical component of the world’s technological future, as paradigm shifts
such as these are fundamental to moving the world forward. Which is why I’m
always looking for the best investments within the world’s fastest-growing
megatrends to best secure your financial future.
To achieve this for 2022, I’ve teamed up with renowned investors Louis Navellier
and Eric Fry, two financial masterminds whose track records speak for
themselves. All three of us will get together today December 8, at 4 p.m. ET,
during our Early Warning Summit 2022, to discuss the opportunities that lie
ahead over the next year.
But while I’m bullish about the promising breakthroughs in synthetic biology, I’m
also a realist. As such, I know there are headwinds in 2022, even in the hot
sectors, that will make choosing the right stocks difficult.
Don’t let 2022 sneak up on you. Join me, Louis, and Eric this Tuesday to get a
head start on alpha in the new year.
The future is knocking. Will you answer?