X-Message-Number: 18716
From: "Peter Christiansen" <>
Subject: Current issue DISCOVER Magazine
Date: Thu, 07 Mar 2002 16:30:24 -0600

DISCOVER Vol. 23 No. 3 (March 2002)
Table of Contents

(part 2)
Body, Cure Thyself
The huge promise of genetic medicine is to cure the diseases we were born to 
inherit. Researchers seem so very close to a breakthrough, yet not one 
single experiment has worked yet
By Jeff Wheelwright
Illustration by Dan winters & Gary Tanhauser



Patients with a form of severe combined immune deficiency disease (ADA-SCID) 
have a defect in a gene that is crucial to immune function. The diagram 
above outlines a recent gene therapy trial that could correct the condition: 
(1) extract defective cells from the bone marrow, (2) insert a virus bearing 
a healthy gene into the cells, and (3) inject the altered cells into the 
patient.
Angie Rojas's cells are about to be returned to her. Taken from her bone 
marrow five days earlier, genetically altered and nourished in the lab, the 
cells nestle in the tip of a syringe, about 45 million of them, a pale nib 
barely visible in the liquid. When the doctor nods and the nurse starts the 
"push," the cells trickle through an IV lock into the teenager's 
bloodstream. It is September 1, 2001, and gene therapy is mounting another 
try.

Jos  Rojas gets up from his seat at the window, eager to keep his daughter's 
face in view. He cranes his head around the monitor at the foot of the bed. 
Lucy, her mother, stays seated, placid as usual. She has been with Angie in 
hospital rooms more times than she can count. This time, she hopes, the 
doctors will arrest the severe immune disorder that has stalked her 
daughter's life. She knows the treatment is experimental. Pressing close to 
Lucy is a young cousin, Denise, whom Angie has invited to the hospital. The 
girl looks around wide-eyed, not sure how to react.

The air outside the window at Childrens Hospital Los Angeles is bright and 
hot. Palm trees dot the steep hillside. From where the relatives sit, the 
famous "Hollywood" sign can be seen, large as life. Although the room is 
full of witnesses besides the family to this unfolding medical drama, there 
is no buzz or chatter, no lights or cameras. A sense of anticipation is 
mixed with anticlimax, as if this were a rerun of a movie that wasn't that 
great to begin with.

What a difference a decade makes. In September 1990 the first human gene 
therapy trial took place at the National Institutes of Health in Bethesda, 
Maryland. The young patient in that experiment, Ashanthi DeSilva, Ashi for 
short, suffered from the same condition as Angelica Rojas. Their rare 
genetic disease is called ADA-SCID severe combined immune deficiency (SCID) 
resulting from the failure of white blood cells to produce a critical 
enzyme, adenosine deaminase (ADA).

Then as now the ultimate aim of the experiment was to insert a healthy form 
of the ADA gene into the patient's cells to restore her immune function. 
Officially, the aim of the trials was to see if transferring the gene was 
safe. The Food and Drug Administration approved both procedures as Phase I 
experiments. In introductory trials like these, an actual therapeutic 
benefit is considered a bonus.

Other coincidences: Ashi and Angie, both daughters of immigrants, are nearly 
the same age Angie, who turned 16 in December, is nine months older. Donald 
Kohn, the doctor-scientist in charge of the trial, had trained with the 
National Institutes of Health team that conducted Ashi's trial. But where 
the publicity for gene therapy in 1990 was intense the NIH researchers held 
a big press conference before Ashi's trial, yet journalists still tried to 
sneak into the hospital to see her Kohn is cautious about attention. "It's 
good for me and for Childrens Hospital in some ways," he says. "But 
publicity probably isn't a good idea for a gene therapy researcher in 2001."

Kohn is alluding to the death, in 1999, of Jesse Gelsinger, a gene therapy 
patient in a quite different experiment in Philadelphia. Gelsinger had an 
extreme reaction to an engineered virus bearing therapeutic genes into his 
liver. The incident has prompted the FDA to tighten rules on researchers 
throughout the field and raised general concerns about safety. "Profound 
damage to public confidence in the discipline of gene therapy has been 
done," declared a past president of the American Society of Gene Therapy 
last summer. The president also took note of the alleged financial conflicts 
of the lead investigator in Philadelphia, whose biotech company stood to 
profit if the trial worked, and of the subsequent revelations at other 
medical institutions of "massive underreporting of patient adverse events." 
The "adverse events" included a half-dozen cases in which patients died of 
their underlying conditions, evidently unrelated to gene therapy. More often 
it happened that fevers and other worrisome complications in the test 
subjects were never brought to the government's attention.

Even before Gelsinger's death, results of direct gene therapy had been 
bafflingly bad. Since the groundbreaking experiment on Ashi, more than 450 
gene therapy trials have been launched in the United States. Although the 
trials have enrolled 4,000 subjects, not one trial has demonstrated that a 
disease can be cured or controlled by altering a person's genes.

Still, the idea of gene therapy remains compelling to fix a disease at its 
root in the DNA. But the technical problems have been twofold: First, how to 
transfer enough of the gene into a patient. Most often viruses are harnessed 
for the task, because viruses are able to insert their genes into cells and 
force them to make foreign proteins. With few exceptions the viruses used 
for gene therapy are altered so they cannot reproduce. Their sole function 
is to sneak into the cell and deliver a packet of DNA, the desired human 
gene.

The second challenge for gene therapy is to get the gene, once inserted, to 
make enough of the desired protein. Natural viruses carry molecular switches 
that regulate their genes, but engineered viruses need help. A DNA sequence 
called a promoter is inserted into the virus; it turns the gene on, 
producing a protein that is supposed to do the work of correcting the 
disease. In ADA-SCID the protein needed is the ADA enzyme.

In 1990, when Ashi got the ADA gene, scientists did not understand the 
hurdles they faced nor did they imagine the string of disappointments to 
come. The initial experiment seemed to work, at least partially, and the 
results were heralded. The "success" of Ashi's gene therapy spurred 
researchers around the nation to launch their own human tests. It was true 
that roughly a quarter of the T cells (a kind of white blood cell) 
circulating in the girl's body did produce the ADA enzyme, an indication 
that the gene was active. But the added gene wasn't making enough of the 
enzyme to protect her from infections. So Ashi, like Angie Rojas during the 
1990s, has continued to require very costly medication. As the cells trickle 
today into Angie's arm, the jury is still out on the case of her 
predecessor, as well as on gene therapy in general.

Don Kohn, who has been sitting at the bedside, has a sudden thought and goes 
over to Lucy and Jos . He gives the parents the most promising news about 
gene therapy it is possible to give. Since the spring of 2000, researchers 
in France have reported increasing success in their treatment of X-SCID, an 
immune deficiency similar to ADA-SCID but more menacing because there is no 
medication for it. First there were two children, then five; now there are 
seven, including a teenager, whose immune systems have been restored by gene 
transfers and are still going strong. A permanent cure? It is still too soon 
to say. The best part is that some of the lab techniques employed by the 
French team were developed by Kohn himself.



Donald Kohn relies on grants to support his team's gene therapy trial at 
Childrens Hospital Los Angeles. "I'm poor but honest and maybe stupid," he 
says.
Photograph by Gillian Laub
At the very outset, medical genetics focused on children and enzyme 
deficiencies. The first disease that was linked to a single genetic trait 
was a condition called alkaptonuria, in 1902. Sir Archibald Garrod, an 
Englishman, studied families in which some of the children produced red or 
black urine and earwax of the same strange color. They also had symptoms of 
arthritis. Their siblings had none of these traits.

Although he didn't know what genes were, Garrod suspected that the children 
with the disorder had inherited a double copy of a "factor" one factor 
received from each parent. Garrod thought that the factor produced an 
enzyme, and if both factors were defective, the lack of the enzyme led to 
the disease. Applying the laws of Mendel to his findings, Garrod sketched 
family lineages for this "inborn error of metabolism."

Alkaptonuria is now listed as a recessive gene disorder, one of hundreds 
categorized since 1902. Genes, as Garrod surmised, are inherited in pairs, 
and a person with a recessive disorder has had the misfortune to acquire a 
bad copy of the gene from each parent. Having a single bad copy of a gene 
isn't generally a problem, because the disorders often involve enzymes, and 
the person's normal copy of the gene can usually make enough of a particular 
enzyme to keep the metabolic pathway in good order. If the enzyme is too 
little or absent, however, the ill effects show up not long after birth, 
when the child has to rely on his or her own metabolic system instead of the 
mother's. According to a recent literature survey by Johns Hopkins 
researchers, "An extraordinarily high fraction of diseases with onset in the 
first year of life are caused by defects in genes encoding enzymes."

The metabolic breakdown that causes ADA-SCID was clarified in the 1970s. The 
ADA enzyme clears the T cells of certain waste products. If the T cells 
cannot do this because of an ADA deficiency, they die. And when T cells die, 
the immune system fails and a SCID disorder erupts.

In the 1980s the gene at the heart of the disorder was identified. Moreover, 
the ADA gene was cloned so that it could be used in experiments. Researchers 
inserted the ADA gene into an engineered mouse virus and then coaxed the 
virus to infect a culture of cells, thus compensating for the genetic flaw. 
The stage was set to bring Angie Rojas and Don Kohn together.

Kohn started his medical career as a pediatric immunologist. At the time he 
left the NIH for Los Angeles, in the late 1980s, Lucy Rojas was trying to 
keep her infant daughter alive. The normal ailments that Lucy had 
experienced with her two older children were so much worse when Angie came 
down with them asthma attacks, fevers spiking to 105, ear infections bad 
enough to require surgery. The mother was told, "If you don't watch this 
child 24 hours a day, she'll pass away."

Kids with undiagnosed SCID usually do die before the age of 2. If diagnosed 
properly, they spend their days sealed in a plastic compartment, like David, 
the heart-wrenching "boy in the bubble," who finally succumbed to X-SCID in 
1984. Although Angie's immune system was full of holes, she appeared to have 
generated just enough ADA enzyme to fight off commonplace germs and viruses. 
As one doctor commented, "She was lucky she didn't walk in front of a bad 
bug."

When the specialists at Childrens Hospital first saw her, in 1991, Angie had 
pneumonia. A bone marrow transplant, which would use cells withdrawn from 
her brother, was considered. Kohn and the other doctors of the transplant 
unit had performed this procedure as a last resort for children with 
leukemia and other grave diseases of the blood. The survival rate for SCID 
patients after a bone marrow transplant was just two children in three, 
however, and those patients did not have pneumonia.

Fortunately, Angie had another option: drug therapy. Her disease was 
diagnosed just as a drug form of ADA, derived from cows, was made available. 
Called PEG-ADA, the medication was injected two times a week. Her mother was 
shown how to give the shots to Angie at home. The treatment cost several 
hundred thousand dollars a year. For the past decade, while bringing Angie 
to the hospital for regular monitoring, the Rojases have managed to have 
their health insurers and a state agency pick up the staggering expense. 
However, the aid will run out long before Angie stops needing the 
medication. Not surprisingly, SCID families and doctors are eager for an 
alternative to high-risk transplants and high-cost medicines.

In Ashi DeSilva's trial 11 years ago, T cells had been filtered from her 
blood, exposed to the gene-bearing virus, and then put back into her system. 
A better target, researchers knew, would be stem cells. Harbored in the 
body's bone marrow, they are not the same as stem cells in an embryo, but 
they are flexible in the same way. They give rise not only to the T cells 
and other components of the immune system, they also program cells to 
recognize a host of different infectious agents. Stem cells lacking the ADA 
gene are not impaired, but every T cell they produce has a fatal flaw. Fix 
the stem cells, the idea is, and all the subsequent T cells should thrive.

It is June, three months before the procedure. The patient and family are 
being briefed. "We'll try to put the gene into the bone marrow," Kohn says 
to Lucy and Jos , "and then we'll give Angie's cells back to her through a 
vein in the hand." He turns to Angie. "It's like getting a bone marrow 
transplant from yourself, but hopefully the marrow has been fixed, and it 
can make all the different cells that you need to fight everything."

The examining room is packed. In addition to Kohn and the Rojas family, 
there are two members of the research team, a hospital public affairs 
representative, a translator, and a social worker. The translator puts 
Kohn's words into Spanish to be certain that Lucy and Jos  understand him, 
and the social worker, taking notes, monitors the ethical aspects of the 
meeting.

This is a consent conference where risks and benefits are discussed, after 
which the parents must decide whether or not to enroll Angie in the clinical 
trial. Wearing black sneakers, black pants, and a blue sweatshirt, Angie 
sits cross-legged on the examining table. Her family and members of the 
hospital team are in chairs in a semicircle around her. Used to being the 
center of medical attention, the girl is quick to smile and quick to speak 
her mind. She is compact and broad-shouldered and plays saxophone in her 
high school band.

Kohn tells the family that "this is a research study, not treatment. It's 
fine if Angie doesn't want to be in the study. She'll get the same care. 
We'd like you to feel you could make this decision without any pressure."

Angie and her mom are already in favor of proceeding, having met with Kohn 
previously. It is Jos  who has to be satisfied. Declining to sit down, he 
asks, "Is this an experiment, then?"

Kohn says yes. Chewing gum and pacing his words to allow translation, he 
reads from the research protocol. He starts by describing ADA-SCID, "a 
genetic disease that Angie inherited. One gene doesn't work in Angie. . . . 
"

A hand shoots up in the corner. "I have a question," Angie says, grinning, 
as if she's back in school. "How did I get the gene? Do you know from which 
parent?"

The doctor asks her to hold the question until later. He methodically 
summarizes the drug and transplant treatments for her disease. Then he takes 
up the precedents for gene therapy. Ashi was the forerunner in the SCID 
field, but Kohn himself conducted a trial in 1993, when excitement about the 
new technique was at its height. Three infants born with ADA-SCID were 
infused with the missing gene. Because the patients were too small to 
provide bone marrow, Kohn had used stem cells from the cord blood of the 
placentas instead. When put back into the children, a small portion of the 
altered stem cells made T cells with the ADA gene, but the gene did not make 
the protein. Still short of ADA, the patients had to remain on medication.

"The T cells with the gene have increased," Kohn says, "but the T cells 
don't have the gene 'on.' We hit a double, not a home run." So in the 
mid-1990s Kohn went back to the drawing board to improve the rate of gene 
transfer. And more work had to be done on the laboratory culture of stem 
cells. So Kohn and his research team developed a more powerful viral vector 
and also improved the growth factors the supplements that nurture stem cells 
while the virus moves the gene into them. The new growth factors were used 
by the French scientists in their promising treatment of X-SCID.

"Will this newer way work better than what we did before?" says Kohn. 
"That's what we're trying to find out."

In discussing the risks of the procedure with the family, he mentions the 
death of Jesse Gelsinger. He doesn't hurry past it, but he doesn't dwell on 
it either. "It was a different virus, and they were trying to put it 
directly into his body. He had a strong reaction and he died. It was 
unexpected. But only he [of all the subjects in the Philadelphia trial] had 
that problem."

Jos  and Angie stir uneasily, but Lucy doesn't blink.

Kohn repeats, "It was unexpected. It taught us bad things can happen, 
though." He points out that the anesthesia Angie must undergo when her bone 
marrow is extracted is more risky, statistically. He goes to the exam table 
and touches Angie for the first time, on the hip. "We take the bone marrow 
from the top-back part of the pelvis." The girl's sneakers crinkle on the 
white tissue paper. "We do it on both sides."

Jos  asks, "Is it possible she won't need shots after this?"

"It's possible. If the gene is working, we'd try to take her off the shots."

Angie's hand shoots up again. "Question. I have always wanted to know: Which 
one of the family had the disease?"

Kohn explains the nature of a recessive condition. "Probably each of your 
parents has one defective gene. You will pass on to your children the ADA 
gene that doesn't work, but if the father has a good gene, your own children 
won't have problems."

"How rare is what I have?"

"We don't know. One in a million? Ten kids each year come forward."

"Wow, lucky me."

The doctor smiles. 'Yes, it's pretty rare. You're unique."

"Would I be the first [in the trial]?"

Kohn indicates yes. The consent is a done deal.



Angie Rojas, left, sits with her sister Suzy, who's 18, in their bedroom in 
Los Angeles. Angie's condition affected her two healthy siblings, she says, 
"because my mom was always at the hospital taking care of me."
Photograph by Gillian Laub
The SCID disorders make a good target for gene therapy experimentation for 
several reasons. One, just a single gene needs correcting. Two, just one 
type of cell needs the gene, the bone marrow stem cell. Three, the 
manipulation of the stem cells can be done in vitro, outside the body, 
providing greater control than does the in vivo technique. In the latter the 
vector has to be more or less squirted toward an organ or a tumor, with no 
assurance that the virus will evade the body's defenses and deliver its 
genetic cargo to the right cells.

Finally, researchers have learned that the regulation of the inserted gene 
does not have to be exact. To combat ADA-SCID or X-SCID, the gene can make a 
lot of protein or a little. Either way, the benefit occurs. Other diseases 
demand a more precise regulation of gene activity.

In the heyday of clinical trials, the early 1990s, gene therapists took on 
many single-gene disorders in addition to SCID. The most prominent was 
cystic fibrosis, a lung condition that kills half its victims by age 30. The 
gene for cystic fibrosis or rather the gene whose flaw spawns the 
disorder was discovered in 1989, raising hopes that researchers could heal 
the damaged airways of patients. After much publicity and a number of 
attempts, the trials were deemed failures. Mucus in the lungs of the 
patients impeded the vectors from penetrating the cells of the respiratory 
tract, and the genes that did manage to get in were neutralized by an immune 
response. Even if the new gene had taken hold, the treatments would not have 
lasted, because the cells lining the airways are constantly replaced. The 
ideal targets would be the parent or precursor cells of lung tissue, but the 
identity of those cells is unknown.

The story of cystic fibrosis is typical. Yet despite the difficulty in 
treating single-gene disorders, researchers have gravitated toward even more 
complex conditions. According to a review in late 2000 by Bret Ball and W. 
French Anderson at the University of Southern California, the great majority 
of gene therapy efforts since 1990 have been directed at cancer, although 
cancer offers no single target in the genome. In distant second place was 
AIDS, with 33 trials launched or proposed. The classic, single-gene diseases 
have accounted for only 50 trials, of which 20 were for cystic fibrosis.

Thus the conditions most likely to yield to the new technology received the 
least attention. The reason is not hard to figure. For rare, inherited 
disorders like SCID, wrote Ball and Anderson, "there is little potential for 
return on investments in expensive research and clinical trials." 
Translation: Drug companies have no motive to invest. By contrast, the "more 
common diseases," such as cancer, heart disease, and AIDS, "make attractive 
targets for pharmaceutical companies." Moreover, experimenters had a ready 
supply of sick people, for whom the risks of enrolling in a gene study 
seemed well worth the while.

The NIH issued a report in 1995 criticizing researchers because they had 
neglected the basic science, especially the animal models, which might have 
worked out the kinks in the procedure. Don Kohn recalls the period: "There 
was such zeal for doing clinical gene therapy. At medical centers the social 
rewards were higher for doing trials, especially on cancers like melanoma, 
where cases were desperate, than for mouse research. The thinking was, you 
didn't know if it would work, but you didn't think it would hurt, 
considering the disease."

It took Jesse Gelsinger's death to shake the field and tighten standards. 
Now, in the wake of the French team's breakthrough with X-SCID, attention is 
once again focused on basic diseases resulting from enzyme deficiencies. 
Anderson, who was co-leader of the trial on Ashi DeSilva, firmly states, as 
he has all along, "If you can't treat SCID, you can't treat anything else."

Angie Rojas lies on her back in the hospital bed, fighting to keep alert. 
While the stem cells are slowly pushed into her arm, she is growing drowsy 
from an infusion of Benadryl, an antihistamine administered before the test 
to guard against inflammation at the injection site. Kohn doesn't fear an 
acute, life-threatening reaction. He believes that 15 years' experience with 
both animal and human SCID subjects, though not guaranteeing a success, has 
minimized the danger to Angie.

Privately, Kohn thinks there's just a one in four possibility that healthy T 
cells will arise in the coming months and rescue her immune system. He is 
uncertain because he doesn't know how many of the stem cells were altered by 
the vector or if they will take hold in her bone marrow.

The nurse making the push, Debra Tumbarello, leans over the patient. "How're 
you feeling, Ange?"

Blearily, she says, "Fine. I'm not dying." Her heart rate has crept up to 94 
beats per minute, probably from anxiety.

In five minutes it's done, and the room starts to empty. Kohn recalls that a 
colleague in his 1993 SCID trial urged that the syringe be saved for the 
Smithsonian Institution because it was a national treasure. This one won't 
be.

Lucy says, relieved, "I expected a big container [of cells]. That's nice it 
was so little." She is wearing a crucifix around her neck.

Shaking Jos 's hand good-bye, the doctor says, "We won't know for sure for 
another two years."

"Ten years of coming here," Angie's father muses. "How many times?" he asks 
his wife.

"If Angie was going to have a reaction," says Tumbarello, "she would have 
had one already."

The girl's heart rate has settled to 80. She sleeps peacefully, new genes 
swirling in her blood.






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RELATED WEB SITES:
For general information, including a wonderful primer on the basic science 
behind gene therapy, see the University of Pennsylvania's Institute for 
Human Gene Therapy page: www.uphs.upenn.edu/ihgt.

For more about gene therapy research at the University of Southern 
California, see cwis.usc.edu/schools/medicine/academic_ 
departments/biochem_molbiol/igm.html.

For updates on political issues and links to ongoing clinical trials, see 
the American Society of Gene Therapy's site: www.asgt.org.

For more about SCID, including various forms and treatments, see 
www.scid.net/scidpid.html.




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