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Gene Therapy Risks Exposed

press-release

 

The Institute of Science in Society

Science Society Sustainability

http://www.i-sis.org.uk

 

General Enquiries sam

Website/Mailing List press-release

ISIS Director m.w.ho

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Biotech century ending?

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This miniseries charts the further collapse of the biotech empire, particular in

the supposedly ‘highly lucrative’ biomedical sector since the latter part of

2000. It is now desperately grasping for support from the taxpayer by hyping

genetics and bio-defence. Don’t be fooled.

 

Genetics & Bio-Defence Research Rescue Biotech Slump

Gene Therapy Risks Exposed

 

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Gene Therapy Risks Exposed

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First test it on patients then study the risks. Dr. Mae-Wan Ho

(m.w.ho) and Prof. Joe Cummins (jcummins) report on the

damning revelations from studies that should have been carried out before

patients were treated.

 

If you wish to see the complete document

(http://www.i-sis.org.uk/full/GTREFull.php) with references, please consider

becoming a member or friend of ISIS. Full details here

(http://www.i-sis.org.uk/membership.php)

 

Geneticist Mark Kay and his team at Stanford University examined a viral vector

that has been used in gene therapy trials of haemophilia and cystic fibrosis. It

turns out that the virus has the potential to cause the same problems that led

to leukemia in the severe combined immune deficiency SCID trial in Paris last

year. The study involves a different vector, made from the adeno-associated

virus (AAV), not known to cause disease in humans. But they now show that the

vector integrates itself more often into genes than other regions of DNA.

 

Unlike the retrovirus used as a vector in the SCID trials, which tend to

integrate into the cell’s genome, AAV integrates much less often. Nevertheless,

geneticists can’t be sure that it does not cause cancer when it does integrate.

 

By extracting DNA from liver cells from mice injected with the AAV vectors, the

team found 72% of the integrations were into a region containing a gene. If it

were random, the vector would have interrupted a gene no more than 40% of the

time.

 

In addition, chromosomal deletions of up to 2kb were detected at all 14

integrations sites examined. Most of the deletions were less than 0.3kb. All the

genes targeted by the AAV vectors were expressed. There was a preference for

introns (non-coding regions of genes) over exons (coding regions).

 

The same tendency to integrate into genes has been discovered earlier for

retroviruses such as HIV-1. Studies on integration in vitro have found that DNA

binding proteins, bound to target DNA, can block integration by obstructing

access of integration complexes. In contrast, DNA bending proteins such as

nucleosomes (protein complexes that wind and package DNA strands into chromatin)

can actually promote integration. On the nucleosome, the positions of maximal

DNA distortion were particularly favoured for integration. The researchers

infected a human lymphoid cell line with HIV or an HIV-based vector, and cloned

524 junctions between viral and cellular DNA. The sequences were then determined

and mapped on the human genome sequence. As a control, 111 sites were generated

by integration in vitro into naked human DNA and their genomic distribution

compared with the in vivo integration sites.

 

Genes were found to be clearly preferred integration targets in vivo but not in

control naked DNA. There was a strong correlation between gene activity and

integration targets, particularly for genes that were active in cells after

infection with HIV vector. Hotspots for integration were also detected,

including a 2.5kb region that contained 1% of the integration events. Some 69%

integration sites were in gene regions, a highly significant departure from

random. For the in vitro naked DNA control, 35% were in transcription units

(gene regions). The human genome is about 33% transcription units, so the

frequency of integration in genes in vitro was not significantly different from

random.

 

The integration sites tend to cluster. No clustering was found in the control.

There were seven regional hotspots of 100kb, four of which contained a gene.

High local gene density correlated with all regional hotspots. The targeted

genes in all four cases were active, and all increased in activity after

infection by 2 to 3 fold.

 

HIV integration was favored in Alu elements (short mobile genetic elements that

are now increasingly recognized to be playing a key role in ‘natural genetic

engineering’ the genome). That may be because Alu elements are enriched in

gene-rich regions.Within genes, integration favored in introns over exons.

 

Thus, sites of HIV integration in the human genome are not random, but enriched

in active genes and regional hotspots, probably due to increased accessibility

to chromosomal DNA in transcribed regions, or it may be promoted at active genes

by favourable interactions between the ‘pre-integration complex’ of the HIV and

locally bound transcription factors.

 

Such results are making researchers seek better ways to target vectors to

specific regions of DNA, and to develop vectors that don’t integrate into DNA at

all. Kay says that he has taken numerous precautions to protect the 14

haemophilias he has treated. Why didn’t he do the experiments before treating

the patients?

 

Meanwhile, a team led by Shun’ichi Kuroda of Osaka University, reported in the

June 29 advance online issue of Nature Biotechnology that they used yeast to

produce nanometer-scale (average 80nm) hollow vesicles bound by lipid membranes

studded with hepatitis B virus (HBV) envelope L protein to act as gene delivery

vehicles. These particles are readily purified by ultra-centrifugation, and are

free of viral genomes. Their hollow interiors can be stuffed with transgenic DNA

or drugs by electroporation (creating temporary holes in the membrane using an

electric field). These were tested both in vivo and ex vivo.

 

A plasmid expressing green fluorescent protein (GFP) was introduced into the L

particles by electroporation, and used to transfect various human cancer cells.

Only human liver carcinoma cell lines HepG2 and NuE took up the vesicles with an

efficiency of nearly 100%. However, another human carcinoma cell line,

PLC/PRF/5, which releases HBV surface antigen particles containing the L

protein, could not be transfected with the L/GFP particles. When injected into

mice carrying graft of tumours, the L/GFP particles were only taken up by

tumours derived from NuE cells, but not in tumours derived from non-liver cell

lines.

 

When the human F9 gene encoding clotting factor IX was incorporated into the L

particles and injected intravenously into mice carrying a tumour derived from

different cells lines, plasma collected showed only mice carrying the liver

carcinoma NuE tumour synthesize the blood clotting protein, and continued for at

least a month. By changing the protein on the surface of the particles, it was

possible to target delivery of drugs or DNA to other cell types. One potential

obstacle to using the method, Kuroda admits, is that although the particles

appear to be nontoxic, they are " somewhat immunogenic " . That’s probably an

understatement, given that similar vesicles were used in an HBV vaccine by the

same team.

 

Opinion is divided as to whether this gene therapy delivery system is as safe as

it seems. It could reduce many of the well-known risks of viral vectors; above

all, the generation of infectious viruses and insertion into genes that could

trigger cancer. Furthermore, viral vectors cannot be targeted to specific cells

lines, and can also induce potent inflammatory immune responses.

 

Kuroda is reported to be developing a " stealth version " of the L particles to

minimize the immune response. However, there is still a lot we don’t know about

the immune response, and previous attempts to manipulate it has all too often

ended in making things worse.

 

For example, a specifically designed myelin basic protein peptide was used in

attempted immunotherapy of multiple sclerosis in a phase II clinical trial in

2000. The peptide was poorly tolerated, and the trial had to be halted. Three

patients developed exacerbations of multiple sclerosis.

 

One nagging question remains in the present study. In the in vivo experiment in

mice successfully transfected with L particles expressing human blood clotting

factor, the protein started disappearing on day 30, and by day 42, had vanished

completely. What happened to the cells that had taken up the L particles? What

happened to the mice? The toxicity test carried out consisted of five four-week

old mice injected with 500ug of the L particles expressing the human clotting

factor 9, which were reported to have " survived for more than 2 weeks,

indicating that the median lethal dose (LD50) is >20mg/kg. " That meant the mice

did die. Is that reassuring? What did the mice die of?

 

If you wish to see the complete document

(http://www.i-sis.org.uk/full/GTREFull.php) with references, please consider

becoming a member or friend of ISIS. Full details here

(http://www.i-sis.org.uk/membership.php)

 

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General Enquiries sam

Website/Mailing List press-release

ISIS Director m.w.ho

 

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