Tired of turkey? Try gene edited, meat-like fungi.
As the world faces an impending protein shortage, the search for sustainable alternatives has led researchers to explore innovative solutions, including gene-edited fungi. With global demand for animal-based protein projected to double by 2050, the urgency to find viable substitutes has never been greater. Plant-based alternatives have not gained the traction expected in recent years, leaving a gap that needs to be filled. A promising contender is *Fusarium venenatum*, a fungus traditionally used as a meat substitute. Researchers at Jiangnan University in China have utilized CRISPR gene-editing technology to enhance this fungus, making it easier to digest and less resource-intensive to produce. Their findings, published in the journal *Trends in Biotechnology*, suggest that this genetically engineered fungus could mimic the taste and texture of meat while offering a significantly smaller environmental footprint compared to conventional livestock farming.
The innovative approach taken by the researchers involved identifying and “knocking out” specific genes in the fungus’s DNA to improve its digestibility and production efficiency. By targeting genes associated with chitin synthase and pyruvate decarboxylase, they reduced the fungus’s cell wall integrity, making it easier for humans to digest. This gene editing not only enhanced the nutritional profile of the fungus but also decreased the resources required for its cultivation. Remarkably, the modified strain requires 44% less sugar to produce the same amount of protein and can do so 88% faster than its unaltered counterpart. When projected on a larger scale, this gene-edited fungus could require 70% less land than chicken farming to yield the same protein output, making it a tantalizing option for addressing the growing global protein demand while mitigating environmental impacts.
Despite the promising developments in gene-edited fungi, the landscape of protein alternatives is evolving rapidly, facing challenges and competition from both plant-based and cultivated meat products. While brands like Beyond Meat and Impossible Foods initially captured consumer interest, they have recently experienced a decline in sales, partly due to concerns over sodium levels and additives. On the other hand, cultivated meat, derived from animal cells grown in laboratories, is attracting significant investment and consumer curiosity, although it remains far from mainstream availability. Legislative hurdles in the U.S. and abroad, such as bans on cultivated meat production, further complicate the acceptance of alternative protein sources. As the demand for protein-rich diets continues to surge, gene-edited fungi could emerge as a critical player in the quest for sustainable food solutions, potentially reducing reliance on livestock and alleviating the environmental burden of traditional animal agriculture.
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It might not seem so obvious when walking past rows of vacuum-sealed Butterball
turkeys
at the supermarket, but the world is on the
brink of a protein shortage
. Global demand for animal-based protein is
expected to double by 2050
and while plant-based alternatives exist,
enthusiasm around them has wavered in recent years
. One possible solution to the brewing protein problem:
gene-edited
fungus.
Using
CRISPR gene editing technology
, researchers from Jiangnan University in China took a fungus that is already used as a meat alternative (
Fusarium venenatum
) and tweaked its DNA to make it easier to digest and less resource-intensive to produce. The result, if brought up to scale, is a genetically engineered fungus that tastes like meat and could have a smaller environmental footprint than traditional livestock or even â
lab-grown
â cell-cultured meat. The studyâs findings were
published today in the journal
Trends in Biotechnology
.
âWe successfully made a fungus not only more nutritious but also more environmentally friendly by tweaking its genes,â corresponding author and Jiangnan assistant professor Xiao Liu
said in a statement
. âGene-edited foods like this can meet growing food demands without the environmental costs of conventional farming.âÂ
A picture of
Fusarium venenatum. Image: Xiao Liu
Turning fungi into âmeatâ
Deriving protein alternatives from fungi and other microbes isnât new. The process typically involves
selecting a microbe and growing it in a steel bioreactor
. Once inside the bioreactor, itâs fed a steady supply of nutrientsâusually a combination of sugars and minerals. Over time, this mixture develops into a large, protein-rich biomass that often looks like a goopy slurry or a soft bread dough, depending on the microbe.Â
Even if that doesnât sound all that appetizing, the resulting biomass can then be processed into a variety of high-protein foods. Unlike raising cattle or pigs, microbial cultivation isnât dependent on seasons or temperature fluctuations. It also can be more sustainable, as the production of animal proteins may
account for around 37 percent of the worldâs greenhouse gas emissi
ons.
The first commercial microbial-protein product,
a type of animal feed called Pruteen,
actually dates back to the 1970s. Today, several other varieties are available for human consumption in grocery stores.
The power of
Fusarium veneatum
When it comes to making these alternatives with fungi, engineers have long preferred
Fusarium venenatum
for
protein farming
because it produces a texture that closely resembles meat. But the production process isnât perfect. This particular fungus has thick cell walls that make it difficult for humans to digest, and it requires a substantial amount of resources to grow it into a biomass thatâs useful as a protein alternative. Thatâs a problem, especially if part of the appeal of microbial protein is reducing the environmental impact associated with traditional animal agriculture.
Thatâs where the
power of CRISPR
comes in. Liu and his colleagues wanted to see if they could identify and âknock outâ the specific genes in the fungusâs DNA to simultaneously boost digestibility and overall production efficiency. It took them some time to find the right targets, but eventually they removed genes associated with the enzymes chitin synthase and pyruvate decarboxylase. Eliminating the chitin synthase-related enzymes reduced the fungusâs cell wall integrity, making it easier to digest. Meanwhile, removing the pyruvate decarboxylase-related enzymes, fine-tuned the fungusâs metabolism, reducing the amount of nutrients needed to produce protein.
This new, edited DNA strain require
d 44 percent less sugar
to produce the same amount of protein as a non-genetically altered strain. It was also able to produce protein
88 percent faster than the original version
. Using these figures as a starting point, the team simulated the environmental impact of producing their fungus at scale compared to traditional animal protein. While thereâs many factors involved such as the type of agricultural infrastructure available to particular counties, the researchers reported that their genetically altered strain would require 70 percent less land to produce the same amount of protein as chickens.
âTaken together, this work provides compelling evidence that CRISPR/Cas-based technology is a powerful gene editing tool that could simultaneously enhance the nutritional properties and sustainability of MP [microbial protein], which will help drive long-term development of the alternative protein industry,â the researchers write in the paper.Â
Related: [
This fermented meat alternative could help halve global deforestation rates
]
Reducing animal consumption is easier said than done
These new findings come amid a period of rapid change in protein alternatives. While popular plant-based meat products, such as those offered by Beyond Meat and Impossible Foods, experienced major commercial success in the mid-2010s, the brands have seen sales decline as of late. They have also faced growing criticism,
whether justified or not
, for containing
higher levels of sodium
and
other additives
compared to animal protein.
Cultivated meat, which refers to animal protein grown in a lab from animal cells, is gaining popular attention and
attracting billions in investment
at the same time. Shoppers are also curious: a 2024
survey
from Purdue University found that two-thirds of respondents said they would try cultivated meat or chicken in a restaurant.Â
Even though this type of cultivated protein is still many years away from mainstream availability (a single lab-grown chicken nugget currently
costs around $50 to produce
), it is already facing backlash. In the United States,
several states including Florida and Mississippi
, have already passed legislation banning the production or sale of cultivated meat. Itâs also not a uniquely American aversion. Last year, Italy officially became
the first country to ban the production
, sale, or import of cultivated meat or animal feed.
All thatâs to say fermented microbial meat alternatives like fungus could have some big barriers to break down, especially as global
demand for protein-rich diets
continues to skyrocket. Increased use of gene-edited fungal foods could mean less land and fewer resources devoted to raising livestock, and fewer creatures living out their final days in a slaughterhouse.Â
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Tired of turkey? Try gene edited, meat-like fungi.
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