Gene-Editing Unintentionally Adds Bovine DNA, Goat DNA, and Bacterial DNA, Mouse Researchers Find
The gene-editing of DNA inside living
cells is considered by many to be the preeminent technological
breakthrough of the new millennium. Researchers in medicine and
agriculture have rapidly adopted it as a technique for discovering cell
and organism functions. But its commercial prospects are much more
complicated.
Gene-editing has many potential uses.
These include altering cells to treat human disease, altering crops and
livestock for breeding and agriculture. Furthermore, in a move that has
been widely criticised, Chinese researcher He Jiankui claims to have edited human babies to resist HIV by altering a gene called CCR5.
For most commercial applications
gene-editing’s appeal is simplicity and precision: it alters genomes at
precise sites and without inserting foreign DNA. This is why, in popular
articles, gene-editing is often referred to as ‘tweaking’.
The tweaking narrative, however, is an
assumption and not an established fact. And it recently suffered a large
dent. In late July researchers from the US Food and Drug Administration
(FDA) analysed the whole genomes of two calves originally born in 2016. The calves were edited by the biotech startup Recombinetics using a gene-editing method called TALENS (Norris et al., 2019).
The two Recombinetics animals had become biotech celebrities for having
a genetic change that removed their horns. Cattle without horns are
known as ‘polled’. The calves are well-known because Recombinetics has insisted that its two edited animals were extremely precisely altered to possess only the polled trait.
However, what the FDA researchers found
was not precision. Each of Recombinetics’ calves possessed two
antibiotic resistance genes, along with other segments of superfluous
bacterial DNA. Thus, apparently unbeknownst to Recombinetics, adjacent
to its edited site were 4,000 base pairs of DNA that originated from the
plasmid vector used to introduce the DNA required for the hornless trait.
The FDA finding has attracted some media attention;
mainly focussed on the incompetence of Recombinetics. The startup
failed to find (or perhaps look for) DNA it had itself added as part of
the editing process. Following the FDA findings, Brazil terminated a
breeding program begun with the Recombinetics animals.
But FDA’s findings are potentially trivial
besides another recent discovery about gene-editing: that foreign DNA
from surprising sources can routinely find its way into the genome of
edited animals. This genetic material is not DNA that was put there on
purpose, but rather, is a contaminant of standard editing procedures.
These findings have not been reported in
the scientific or popular media. But they are of great consequence from a
biosafety perspective and therefore for the commercial and regulatory
landscape of gene-editing. They imply, at the very least, the need for
strong measures to prevent contamination by stray DNA, along with
thorough scrutiny of gene-edited cells and gene-edited organisms. And,
as the Recombinetics case suggests, these are needs that developers
themselves may not meet.
Understanding sources of stray DNA
As far back as 2010 researchers working
with human cells showed that a form of gene-editing called Zinc Finger
Nuclease (ZFN) could result in the insertion of foreign DNA at the
editing target site (Olsen et al., 2010). The origin of this foreign DNA, as with Recombinetics’ calves, was the plasmid vector used in the editing process.
Understanding the presence of plasmid
vectors requires an appreciation of the basics of gene-editing, which,
confusingly, are considerably distinct from what the word ‘editing’
means in ordinary English.
Ultimately, all DNA ‘editing’ is really
the cutting of DNA by enzymes, called nucleases, that are supposed to
act only at chosen sites in the genome of a living cell. This cut
creates a double-stranded break that severs (and therefore severely
damages) a chromosome. The enzymes most commonly used by researchers for
this cutting are the Fok I enzyme (for TALENS type editing), Cas9 (for CRISPR), or Zinc Finger Nucleases (for ZFN).
Subsequent to this cutting event the cell
effects a repair. In practice, this DNA repair is usually inaccurate
because the natural repair mechanism in most cells is somewhat random.
The result is called the ‘edit’. Researchers typically must select from
many ‘edits’ to obtain the one they desire.
Like virtually all enzymes these nucleases
are proteins. And like most proteins they are somewhat tricky to
produce and relatively unstable once made. Typically, therefore, rather
than produce the DNA cutting enzymes directly, researchers introduce
vector plasmids into target cells. These vector plasmids are circular
DNA molecules that code for the desired enzyme(s). (Vector plasmid DNA
may also code for the guide RNA that CRISPR editing techniques require).
What this means, in practice, is that TALENS, Cas9 and the other
cutting enzymes end up being produced by the target cell itself.
Introducing DNA rather than proteins is
thus much easier, research-wise, but it has a downside: non-host (i.e.
transgenic) DNA must be introduced into the cell that is to be edited
and this DNA may end up in the genome.
Plasmid vectors are not simple. As well as
specifying the nucleases, the vector plasmid used by Recombinetics
contained antibiotic resistance genes, plus the lac Z gene,
plus promoter and termination sequences for each of them, plus two
bacterial origins of replication. Each of these DNA components comes
from widely diverse microbes.
As Olsen et al. and the FDA showed, using
both TALENS and ZFN types of DNA cutters can result in plasmid vector
integration at the target site. In 2015 Japanese researchers showed that
DNA edits made to mouse zygotes using the CRISPR method of gene editing
are also vulnerable to unintended insertion of non-host DNA (Ono et al., 2015).
Since then, similar integrations of foreign DNA at the target site have been observed in many species: fruitflies (Drosophila melanogaster), medaka fish (Oryzias latipes), mice, yeast, Aspergillus (a fungus), the nematode C. elegans, Daphnia magna, and various plants (e.g. Jacobs et al., 2015; Li et al., 2015; Gutierrez-Triana et al., 2018).
Other sources of stray DNA
The vector plasmids themselves are not the
only source of potential foreign DNA contamination in standard
gene-editing methodologies.
Earlier this year the same Japanese group showed that DNA from the E. coligenome can integrate in the target organisms’ genome (Ono et al. 2019). Acquisition of E. coli
DNA was found to be quite frequent. Insertion of long unintended DNA
sequences occurred at 4% of the total number of edited sites and 21% of
these were of DNA from the E. coli genome. The source of the E. coli DNA was traced back to the E. coli cells that were used to produce the vector plasmid. The vector plasmid, which is DNA, was contaminated with E. coli genome DNA. Importantly, the Japanese researchers were using standard methods of vector plasmid preparation.
Even more intriguing was the finding, in the same paper, that edited mouse genomes can acquire bovine DNA or goat DNA (Ono et al.,
2019). This was traced to the use, in standard culture medium for mouse
cells, of foetal calf serum; that is, body fluids usually extracted
from cows. This serum contains DNA from whichever animal species it
happened to have been extracted from, hence the insertion in some
experiments of goat DNA (which occurred when goat serum was used instead
of calf serum).
Even more worrisome, amongst the DNA
sequences inserted into the mouse genome were bovine and goat
retrotransposons (jumping genes) and mouse retrovirus DNA (HIV is a
retrovirus). Thus gene-editing is a potential mechanism for horizontal
gene transfer of unwanted pathogens, including, but not limited to,
viruses.
Other potential sources of unwanted DNA
also exist in cell cultures used for gene editing. In 2004 researchers
observed that when cells from a hepatoma cell line were caused to have
DNA breaks, some of these breaks were filled by hepatitis B virus
sequences (Bill and Summers, 2004). In other words, pathogens contaminating the foetal serum, such as DNA viruses, should also be a source of concern.
Furthermore, the insertion of superfluous
DNA from other species is likely not restricted to the intended target
site. As is becoming appreciated, gene-editing enzymes can act at
unwanted locations in the genome (e.g. Kosicki et al., 2018).
Accidentally introduced DNA can also end up at such sites. This has
been shown for human cells and also plants using CRISPR (Kim and Kim
2014; Li et al., 2017; Jacobs et al.,
2015). There is every reason to suppose that the more exotic DNAs
mentioned above can integrate there as well, but this has not been
specifically tested for.
Implications of superfluous DNA in edited cells
In summary, the new findings are very
simple: cutting DNA inside cells, regardless of the precise type of gene
editing, predisposes genomes to acquire unwanted DNA. The unwanted DNA
may come from inside the edited cell, or it may come from the culture
medium, or it may come from any biological material added to the culture
medium, whether accidentally or on purpose. Therefore, it is not hard
to imagine, for instance, gene-edited animals becoming the breeding
stock that leads to the development or spread of novel or unwelcome
viruses or mycoplasmas.
Stuart Newman of New York Medical College
is a cell biologist, a founding member of the Council for Responsible
Genetics, and Editor-In-Chief of the journal Biological Theory.
According to him, the addition of DNA originating from cell culture “is
something that has not been broached in the discourse around safety of
CRISPR and other gene modification techniques.”
In the case of gene-editing intended to
generate altered living organisms, cell culture media “contain genes
that could cause developmental problems if reincorporated by CRISPR/Cas9
into the zygote genome in extra numbers and uncontrolled chromosomal
sites.” says Newman.
“I have little doubt E. coli DNA
has been inadvertently incorporated into many CRISPR targets, and it is
likely to cause problems, as it has in the horned cattle.”
Similar concerns apply to human
applications. The incorporation of DNA from other species has not
publicly been raised in connection with the gene-edited human babies of
researcher He Jiankui. Clearly, it should be. From what cell types, for
example, did He Jiankui purify the proteins he presumably used to edit
the CCR5 gene? Rabbit cells? Insect cells? Those, at least, are the
standard methods.
The second important conclusion, and what
the Recombinetics case exemplifies, is that researchers are often not
looking for stray DNA. If they were to look, many more examples would
likely be reported. We can conclude this because the research cited
above used standard methods of gene-editing. The only untypical aspect
was the extra effort put towards detecting superfluous DNA.
Gene-editing versus GMOs
What these recent findings also highlight
is a more general, but little-discussed, aspect of gene-editing.
Although the goals of gene-editors and genetic engineers are assumed to
be very different, their standard methods are, in practice, virtually
indistinguishable.
Consider crop plants, which are where much
of the immediate commercial interest in gene-editing resides. To edit
plants, DNA, in the form of vector plasmid, is introduced into plant
cells. In contrast to methods of animal gene-editing, this vector
plasmid is necessary (and not optional) since proteins cannot penetrate
plant cell walls. This vector plasmid must access the cell interior,
which requires either a gene gun or infection with the DNA-transferring
bacterium Agrobacterium tumefaciens. Lastly, in-vitro cell culture is used to regenerate the edited cells into whole plants.
Gene guns, tissue culture, and A. tumefaciens
are all standard genetic engineering methods for crops. They also all
create mutations. That is, they damage DNA. Depending on the specifics
of the method used, such as the length of time in tissue culture, the
collective result can be ten thousand mutations per genome (Wilson et al., 2006; Latham et al., 2006). For gene-editing of crops this means that one on-target mutation may be dwarfed by thousands of off-target ones.
The other necessary comparison with GMOs
is their track record of being found, long after commercialisation, to
have unintended foreign DNA present in their genomes. Cornell’s
virus-resistant papaya, released in Hawai’i, turned out to contain at
least five (and possibly six) separate fragments of transgenic DNA.
Cornell had previously told regulators its papaya contained two
transgenes (Ming et al., 2008).
Monsanto’s Roundup Ready Soybean, by then grown on 96% of US soybean
acres, was found by independent researchers to have substantially more
foreign DNA than Monsanto had claimed (Windels et al., 2001).
So, if one only listened to the rhetoric
contrasting ‘precise’ ‘tweaks’ of gene-editing with ‘messy’, ‘random’
genetic engineering one would hardly suspect that, when it comes to
plants, and often to animals as well, there is little difference between
the reality of gene-editing and that of genetic engineering.
Are there solutions to the presence of superfluous DNA?
Solutions to the presence of superfluous
DNA (at or distant from the editing site) come in two basic forms:
prevention, or detection followed by removal.
An obvious preventive step is to avoid the
use of vector plasmids and undefined culture media (undefined media are
those containing fluids or extracts from living organisms). Another is
to explicitly breed (backcross) gene-edited animals and plants to remove
superfluous DNAs. A third is to sequence their whole genome, compare it
to the parent genome, and select only unaltered lines, if they can be
found (Ahmad et al., 2019).
However, these remedies are effortful.
They are time-consuming and costly, or not yet fully developed, or only
available for some species. These are also solutions that nullify the
advantages of speed and ease that are often the stated reasons for
editing in the first place.
The requirements for expertise and effort
do much to explain the second major problem, which is that the industry,
and not just Recombinetics, is not showing much interest in
self-examination. Far greater even than the GMO industry before it,
there is a cowboy zeitgeist: blow off problems and rush to market. Thus
most gene-editing companies are reluctant to share information and
consequently very little is known about how, in practice, many of these
companies derive their ‘gene-edited’ products.
Many countries are at present formulating regulations that will go a long way to determining who benefits and who loses from any potential benefits that gene-editing may have. But in any event, these results provide a compelling case for active government oversight.
It is not just regulators who need to step
up, however. Investors, insurers, journalists, everyone, in fact,
should be asking far more questions of the scientists and companies
active in gene-editing. Otherwise, boom is likely to stray into bane.
*
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The original source of this article is Independent Science News
Copyright © Dr. Jonathan Latham, Independent Science News, 2019
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