The History of the 22q11.2 Deletion
by Donna M. McDonald-McGinn, M.S. and Elaine H. Zackai, M.D.
What is the 22q11.2 deletion?
Well, its history is quite interesting and worth reviewing, but first we need to
step back and describe some terminology, so that everyone reading this will begin
on the same footing.
As you may know, a syndrome is really a collection of findings that has been seen
recurring over and over again in patients. For example, one common group of associated
features includes: a heart problem; an opening in the roof of the mouth (often described
as a cleft palate); and a difference in learning style. Syndromes are generally names
after the person or persons who first described the collection of findings. Once
an underlying cause is identified, the name may be changed to reflect the specific
chemical abnormality, chromosome difference, or gene change that caused the problem.
Genes are made up of a chemical called DNA and are housed on larger structures called
chromosomes. Most people have 23 pairs of chromosomes (46 total), with one of each
pair coming from the mother and the other from the father. Chromosomes are number
1 through 22; the 23rd pair are called sex chromosomes because they determine a person's
sex (male or female). The chromosomes are found in every cell in the body. Cells
are so small that they, and the chromosomes they contain, can only be seen under
a microscope.
Since genes are housed inside the chromosomes, they can't be seen under a microscope,
but they can be measured by using special "molecular" tests. A good way
to think about chromosomes and genes is to compare them to a train. A train has a
number of box cars just as a chromosome has a number of stripes. We can see the box
cars when we look at a train, just as we can see the chromosomes and their stripe
patterns when we look under the microscope. We cannot, however, see the packages
inside the boxcar without first opening the door. The same is true for a chromosome
- the genes are the packages inside.
When a baby is conceived with either too much or too little chromosomal material,
birth problems can occur. This may include a whole extra chromosome, as in Down syndrome
(an extra number 21), a whole missing chromosome, as in Turner syndrome (a missing
X), a piece of material missing or extra, or a complex rearrangement of chromosomal
material. When chromosomal material is missing or extra, genes are generally missing
or extra. Since genes are the blueprint of the body, when they are lost or extra,
the body's blueprint changes, frequently leading to birth problems and learning differences.
So again you ask, what is the 22q11.2 deletion?
People with a 22q11.2 deletion have a very small piece of chromosome 22 missing (thus
it is called a deletion). The q11.2 tells everyone who works in genetics that the
area missing is in a very specific spot on the "q" arm, which is also called
the long arm of the chromosome. (Chromosomes are divided into two parts, the top
half being called the "p" arm and the bottom half called the "q"
arm.) It is very important to know the location of a missing piece of chromosomal
material in order to make some general comparisons (although no two people are exactly
alike), because if two children have different areas of the same chromosome missing,
it would be like comparing "apples to oranges".
In 1981, Dr. de la Chapelle in France, and in 1982, Richard Kelley, M.D., along with
Elaine Zackai, M.D. and Beverly Emanuel, Ph.D. at the Children's Hospital of Philadelphia
in the U.S.A., found that patients with DiGeorge syndrome had a rearrangement of
chromosome 22 which caused them to be missing a very small piece of chromosomal material
on the long arm (q11.2) of chromosome 22. This rearrangement was able to be seen
under the microscope. This piece of information is important, as you will see when
you read on, because most 22q11.2 deletions are not seen under the microscope because
they are too small.
Patients with DiGeorge syndrome have a collection of findings which include: a characteristic
heart defect (interrupted aortic arch, truncus arteriosus, conoventricular septal
defect, tetralogy of Fallot, etc.), problems with calcium, trouble with infection
(due to abnormalities of the thymus gland), and occasionally a cleft palate. Dr.
Angelo DiGeorge, who first diagnosed this collection of findings, was and still is
an endocrinologist at St. Christopher's Hospital for Children in Philadelphia.
Over the years, Dr. Emanuel's group at the Children's Hospital of Philadelphia worked
very hard to establish the fact that 25% of patients with DiGeorge syndrome had a
visible deletion of material on chromosome 22 when they looked under the microscope.
But they were still puzzled about the other 75% of patients with DiGeorge syndrome
who did not have a visible deletion. In 1991, Deborah Driscoll, M.D., a member of
Dr. Emanuel's laboratory group, detected a submicroscopic deletion of chromosome
22q11.2 in the majority of patients with DiGeorge syndrome using special "molecular"
tests. This meant that although you could not see the material under the microscope,
you could prove that the piece was absent by using a special DNA test called FISH
(fluorescence in situ hybridization). This test works like a lock and key. The person
in the laboratory has the key which lights up (fluoresces) if it finds its matching
lock in the chromosomes. If the lock is missing from one of the pair of chromosomes
22s, only one chromosome 22 will light up in the area in question (q11.2), confirming
that the patient is missing material on chromosome 22.
The majority of patients who had a 22q11.2 deletion, which caused their DiGeorge
syndrome, did not have an affected parent, therefore, the change in their chromosome
22 was a "new mutation" in them. This was and still is important information
for families, because, if the parents' chromosomes are normal, then the chance of
recurrence in a future pregnancy is quite low. About 10% of the time, a parent is
also affected with some medical problem like a heart defect and also has the 22q11.2
deletion. If the deletion is present, then that individual has a 50% chance of passing
on the chromosome 22 with the deletion to his or her children. The chance of having
more than one child affected when the parent has the deletion is random (like the
chance of flipping a coin twice in a row and finding "heads" twice in a
row). When a child receives the chromosome 22 with the deletion, the medical problems
can be quite variable. For example, from a very mild heart problem to a very severe
heart problem, or no heart problem at all.
So, what else happened in the history of the 22q11.2 deletion?
Well, backing up a bit, in 1968, William Strong, M.D., a physician from Cleveland,
reported an association of cardiac abnormalities (right sided aortic arch), learning
differences, and a characteristic facial appearance in four members of one family.
In 1976, Dr. Kinouchi, a physician in Japan, reported a typical facial appearance
specifically seen in patients with heart problems (conotruncal anomalies) and called
it conotruncal anomaly face syndrome (CTAF). IN 1978, Robert Shprintzen, Ph.D., a
speech pathologist from New York, described a disorder running in families where
the patients had a combination of cleft palate or VPI (velopharyngeal-incompetence
- the failure of the back of the palate and the throat to close the space connecting
the mouth and the nose during normal speech, which causes the patient to sound like
he or she has a cold), heart defects, learning disabilities, and a characteristic
facial appearance. He called this condition velocardiofacial syndrome (velo means
palate or roof of the mouth, cardio stands for heart, and facial stands for the typical
facial characteristics seen in their patients). In 1980, Dr. Shimizu, also of Japan,
noticed that there were similarities between the patients who were diagnosed with
CTAF and those with DiGeorge syndrome. Dr. Shimizu described one patient known to
have findings of both DiGeorge syndrome and CTAF. In 1981, Dr. Shprintzen reviewed
the patients reported to have CTAF and suggested that they had velocardiofacial syndrome.
Following Dr. Shprintzen's reports of patients with velocardiofacial syndrome (VCFS
for short), Tony Lipson, M.D., a geneticist from Australia, emphasized the wide variability
in findings between patients and even with the same family. Dr. Lipson also suggested
that patients who had a palatal problem generally responded well to treatment. He
noted that since many of the findings in the patients with VCFS were subtle, that
pediatricians may not suspect the diagnosis at all - leading to delay in treatment
for the hypernasal speech (speech that sounds like it is coming through the nose).
He made a plea for diagnosis of this syndrome as early as possible so that treatment
could begin. However, there was no good test available in the newborn period - until
recently.
The story continues.
In 1990, C.A. Stevens, M.D., from Utah, reported a patient with DiGeorge syndrome
whose father had a cleft palate, problems fighting infection, and facial features
consistent with VCFS. He proposed that all previously reported patients with a parent
and child affected with DiGeorge syndrome were examples of VCFS. This followed a
report by Rosalie Goldberg, M.S., from New York, suggesting an overlap of findings
between patients with DiGeorge syndrome and VCFS, such as calcium problems and problems
with infection. When Dr. Lipson reviewed his patients with VCFS, 6 of 38 patients
had features of both DiGeorge syndrome and VCFS. Recently Drs. Weyerts and Jones
from San Diego found that the medical problems seen in older patients with DiGeorge
syndrome and VCFS were indistinguishable. So, in 1992, Dr. Driscoll, again at the
Children's Hospital of Philadelphia, demonstrated that the vast majority of patients
with VCFS had a 22q11.2 deletion. In fact, she found that this deletion was no different
from that seen in patients with DiGeorge syndrome. This finding explained the reason
for the overlap in clinical findings between the two diagnoses, and therefore supported
the idea that these were in fact the same syndromes.
The story enlarges even further.
Since Dr. Driscoll's discovery that DiGeorge syndrome and VCFS are in fact the same
diagnosis, other "syndromes" have been added to the list of diagnoses which
have the 22q11.2 deletion as the underlying cause of the patients' problems. These
presently include CTAF, as described by the Japanese, and one type of Opitz G/BBB
syndrome. Opitz G/BBB syndrome was first described by John Opitz, M.D., a physician
in Montana. The hallmark features include: hypertelorism (widely-spaced eyes), hypospadias
(the opening of the penis is not at the tip), swallowing problems, and noisy breathing.
These findings were extremely variable, from severe to mild, in affected family members.
In 1995, Donna McDonald-McGinn, M.S. and Elaine Zackai, M.D., at the Children's Hospital
of Philadelphia, reported a patient with Opitz G/BBB syndrome, without overlapping
features of DiGeorge syndrome or VCFS, in whom a 22q11.2 deletion was found. In addition,
they reported patients with overlapping features of the three syndromes, including
a father and child, all of whom were found to have a 22q11.2 deletion. Since their
report, Julie Fryburg, M.D., a physician from Virginia, and Drs. Lacassie and Arriza
from New Orleans, independently reported patients with features of both Opitz G/BBB
syndrome and VCFS and a 22q11.2 deletion.
So, in summary, the 22q11.2 deletion is thought to be the underlying cause of the
medical problems associated with the vast majority of patients with DiGeorge syndrome,
velocardiofacial syndrome, conotruncal anomaly face syndrome, and some patients with
Opitz G/BBB syndrome. Furthermore, the diagnostic name which is given to a particular
patient's set of findings is generally determined by the subspecialist to whom the
patient presents. For example, patients diagnosed with CTAF presented to cardiology
because of their heart defect. The same is true for many patients with DiGeorge syndrome
who often had problems with calcium and their thymus gland in addition to their heart
problems. Patients diagnosed with VCFS were usually older, presenting to the cleft
palate clinic for follow-up due to a cleft palate or VPI. And lastly, patients with
Opitz G/BBB syndrome often presented to the ear, nose and throat doctors due to their
noisy breathing. Thus, the perception that these diagnoses were really distinct entities
may ultimately be explained by the bias of each medical group's area of expertise.
We at the Children's Hospital of Philadelphia, therefore, refer to all patients with
a 22q11.2 deletion by their cytogenetic name, patients with a 22q11.2 deletion (as
we do in other chromosomal disorders, i.e. 4p-, 18q+, trisomy 21, etc.) which allows
all physicians involved to immediately understand the cause of the problem, the recurrence
risk, and the variable prognosis. It also allows physicians to compare their patients
to children in the literature with the exact same thing rather than possibly comparing
"apples to oranges".
22q and You
"Decicated to Teaching, Learning, and Caring for patients with a 22q11.2 deletion"
Clinical Genetics Center - The Children's Hospital of Philadelphia
Wood Bldg Room 1080 - One Children's Center - 34th St & Civic Center Blvd - Phila,
PA 19104
Phone (215) 590-2920 - Fax (215) 590-3298 - Email: mcginn@email.chop.edufile:///SLIDE%20CAMERA/Applications/Visual%20Page%201.0.2/22q&you/medicalneeds.html