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Vol. 10, Issue 8, 1065-1070, August 2000
INSIGHT/OUTLOOK
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 REFERENCES
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A near-complete sequence of the human genome is now
available, and many efforts are currently focused on
the next logical biomedically relevant target 
the mouse genome.
Given limited resources, which vertebrate genome(s) should be tackled
after that? Reasonable candidates include other well-studied model
organisms such as Rattus rattus (the rat), Xenopus
laevis (the African clawed toad), and Danio rerio (the
zebra fish). Over the last few years, some have been advocating a
genomic approach toward understanding our closest evolutionary
relatives, the great apes (McConkey and Goodman 1997
; Paabo 1999;
McConkey et al., 2000). Pan troglodytes (the chimpanzee) and
Pan paniscus (the bonobo) share nearly 99% of human genomic
sequences (see Box 1 for discussion) (King and Wilson 1975; Sibley and
Ahlquist 1984; Caccone and Powell 1989; Ruvolo 1997; Goodman et al.
1998; Satta et al. 2000). Thus, it is cogently argued that knowing the
complete genome of at least one of these species will give us a window
into genes that contribute to humaness (the chimpanzee is the first
choice, because we know more about this species than we do about the
bonobo). The emergence of humans can be regarded as one of the major
transitions in evolution (Szathmary and Smith 1995), and the complete
explanation of this phenomenon ranks as one of the greatest unsolved
mysteries of science.
Taxpaying citizens might argue that, given limited resources, this
lofty and anthropocentric pursuit should not take precedence over the
pragmatic value of sequencing genomes of model organisms that have
already been better studied by a variety of biomedical and genetic
approaches. Moreover, it might be suggested that this is a matter for
the National Science Foundation (NSF) to deal with, not the National
Institutes of Health (NIH). Programs within the NSF are currently
considering a Human Origins Initiative (Weiss and Yellen 2000).
However, I would like to suggest that there is clear and compelling
biomedical value to giving high priority to the complete sequencing of
the chimpanzee genome and that of at least one Old World monkey. The
experience of primate centers and zoos over the last century indicates
that there are many interesting differences in disease frequency and
severity between humans and great apes such as the chimpanzee. Whereas
the evidence is sometimes fragmentary or inconclusive, the nature and
significance of these medical conditions (including AIDS, Alzheimer's
disease (AD), cancer, malaria, and perimenopausal complications) are
sufficient to draw attention to the issue. After all, extrapolating
findings in physiology and pathology from mice, rats, toads, or fish to humans can be difficult, because of our significant physiological and
genetic differences from these species. In contrast, the >99% identity of amino acid sequences of most chimpanzee and human proteins
(see Box 1) predict a stronger likelihood of finding genetic explanations for any disease differences. Studies of the chimpanzee genome could be considered a logical extension of the current emphasis on exploiting sequence differences between various human groups to identify important disease susceptibility genes. For
this and other reasons, the cost of a chimpanzee genome project should
also be much less than for the original Human Genome Project. Also, as
discussed below, the knowledge gained could be of much value in our
efforts to conserve and care for the great apes themselves.
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Some pathological states in humans seem to represent the normal
situation in chimpanzees, including craniosynostosis (closure of the
skull sutures in the perinatal period) (Cohen 1991), general leukocytosis (a high white blood cell count) (Hodson et al. 1967; McClure et al. 1972) and extensive hypertrichosis (hairiness). Several
other diseases or physiological states of humans appear to be rare or
markedly attenuated in the chimpanzee (Scott 1992). Some of these
diseases can be attributed to anatomic differences between the species,
including protracted, painful, and dangerous childbirth (resulting from
the larger head of the human fetus and the altered pelvis of the
bipedal human female), neonatal cephalhematoma (the common
subperiosteal blood clot of the new born human skull bones), wisdom
tooth impaction (resulting from the reduced jaw size in humans and the
lack of a post-molar gap), and various diseases attributed to gravity
effects on bipedal humans (vertebral osteoarthritis, intervertebral
disc protrusion, varicose veins, and hemorrhoids). There are also a few
anatomically unique diseases of great apes that do not occur in humans,
such as infection of the pharyngeal air sacs (an organ that is absent in humans) (Strobert and Swenson 1979). The rarity of certain other
human conditions such as sexually transmitted diseases and severe
hypercholesterolemia in great apes is possibly explained on a
behavioral/cultural basis, as they can be induced experimentally in the
latter (Scott 1992). The higher frequency in humans of anatomical
disorders of the central nervous system such as hydrocephalus is also
intriguing (Scott 1992), but could be explained on the basis of
increased perinatal trauma. However, many other differences cannot be
explained on any obvious behavioral, dietary, anatomic, cellular, or
biochemical basis. It is these differences that justify the biomedical
imperative of the title of this article.
The best known of such differences is the failure of HIV infection to
progress to AIDS in the chimpanzee. Prior to the realization that HIV-1
was originally transferred from chimpanzees to humans (Gao et al.
1999), a large number of chimpanzees were experimentally infected with
HIV derived from human patients (Alter et al. 1984). Many years went by
before a single chimpanzee finally manifested progression to a true
AIDS-like syndrome (Novembre et al. 1997). However, the HIV isolated
from this individual is evidently an unusual mutant that evolved during
the prolonged incubation period, as it rapidly produced an AIDS-like
syndrome upon transfer to another chimpanzee. Despite many studies
attempting to find the answer (for examples, see Arthur et al. 1989;
Gendelman et al. 1991; Di Rienzo et al., 1994; Heeney et al. 1995;
Ehret et al. 1996; Benton et al. 1998; Bogers et al. 1998; Pischinger
et al. 1998), the mystery remains this retrovirus seems to live in a
symbiotic state within the chimpanzee immune system, whereas it almost
routinely destroys the helper T cells of humans. Although the
evolutionary reason for this is now reasonably clear (chimpanzees are
probably a natural reservoir and humans are not), the mechanistic explanation remains obscure. The ability to compare the genomes of the
two species could be highly instructive. In the best of all possible
worlds, the knowledge gained could enable humans who are unfortunate
enough to acquire HIV to live in a symbiosis with the infection, and
the biomedical issue then becomes primarily one of preventing
transmission to other individuals. Another virological mystery of less
certain significance is the high frequency of endogenous foamy
spumaviruses in great apes in contrast, humans rarely get infected,
and only upon exposure to great apes (Schweizer et al 1995; Goepfert
et al. 1996).
AD is a common and devastating disease causing dementia in elderly
humans whose brain pathology is characterized by the accumulation of
amyloid plaques (consisting of fragments of the amyloid precursor protein) together with neurofibrillary tangles (paired helical filaments containing a hyperphosphosphorylated form of the
neurofilament protein tau). Whereas the clinical diagnosis of AD might
be difficult in a great ape, the complete pathological lesion including
the neurofibrillary tangles has never been observed in the brains of
elderly chimpanzees (Gearing et al. 1994). In contrast, age-matched samples from human brain specimens show a significant rate of these
classic lesions, often well before the symptomatology has become
evident (Braak and Braak 1997; Duyckaerts and Hauw 1997; Silverman et
al. 1997; Price and Morris 1999). Neurofibrillary tangles can even
exist in human brains independent of plaques, starting virtually at
birth and reaching a 50% prevalence by age 48 (Duyckaerts and Hauw
1997; Silverman et al. 1997). This difference is all the more
remarkable, given that chimpanzees express the ancestral apoE4 allele
of apolipoprotein-E (Hanlon and Rubinsztein 1995; Hacia et al.
1999), which is associated with the highest risk of AD in humans. The
fact that the full-blown lesion of AD has also not been observed in
other long-lived animals (such as elderly elephants) (Cole and Neal
1990) reinforces the significance of this finding, and makes a
comparison between human and the corresponding chimpanzee genes of
great potential benefit.
Of all of the different forms of malaria, Plasmodium
falciparum is the most aggressive and acutely life threatening; it
is a major cause of mortality worldwide. Chimpanzees seem immune to
infection with this parasite, and, instead, get infected by its close
relative Plasmodium reichnowii, which apparently does not make
them very ill (Escalante and Ayala 1994; Escalante et al. 1995; Qari et
al. 1996). This resistance to falciparum malaria was clearly
demonstrated when captive chimpanzees in Gabon did not get infected
even in the face of a high rate of attack among their keepers, who were
exposed to the same mosquito-containing environment (Ollomo et al.
1997). Even with some other forms of malaria, the parasite burden in
experimentally infected chimpanzees only becomes substantial after a
splenectomy (Morris et al. 1996; Sullivan et al. 1996). Although one
cannot predict which factors are most important (e.g., do different
mosquito strains prefer human vs. chimpanzee skin?), the bulk of the
evidence predicts that genetic differences determine at least a portion
of the observed differences in susceptibility. The knowledge gleaned
from comparative studies of the relevant parasite genomes as well as
the human and chimpanzee genomes could be quite informative.
Another surprising difference appears to be in the frequency of the
most common human cancers, which are epithelial neoplasms such as
carcinomas of the breast, ovary, lung, stomach, colon, pancreas, and
prostate. Whereas these cancers cause >20% of deaths in modern
human populations (Parker et al. 1997), an extensive literature
suggests that the cancer incidence rates for the non-human primates is
only ~2%-4% and seems to be even lower in the great apes (McClure
1973; Seibold and Wolf 1973; Schmidt 1978; Beniashvili 1989; Scott
1992). Although the numbers of well-documented autopsies on great apes
are relatively small (in the hundreds), several factors suggest that
this apparent difference is not due to ascertainment bias. First, there
are several reports of apes having leukemias and lymphomas (Manning and
Griesemer 1974; Gardner et al. 1978), which comprise only a minority of
malignancies in humans. Second, although age is certainly a factor
affecting carcinoma incidence, great apes often live into their forties
and fifties (and even sixties) in captivity. Furthermore, carcinomas
certainly occur at a younger age in other animals, including monkeys
(DePaoli and McClure 1982; Uno et al. 1998). Third, many asymptomatic
benign tumors of various organs have been accurately identified and
characterized during autopsies of great apes (McClure 1973; Seibold and
Wolf 1973; Graham and McClure 1977; Beniashvili 1989; Scott 1992), indicating that the autopsies were well performed. Finally, the diet
and environmental exposure of great apes living in captivity is
certainly not free of the factors thought to be involved in carcinogenesis in humans. Further epidemiological studies (ideally a
worldwide survey of all autopsy records of all major primate centers
and zoos) should be done to confirm this tantalizing suggestion from
the existing literature. Meanwhile, because cancer is clearly a disease
of the genome (Hanahan and Weinberg 2000), comparative genomics should
proceed with the objective of identifying which genes might be involved
in this apparent difference. In this regard, it is of interest that a
cell surface sugar modification that is lost in the human lineage due
to a genomic mutation (Chou et al. 1998; Muchmore et al. 1998b) is
reported to reappear in human cancers.
Another interesting difference appears to be in the incidence of the
late complications of viral hepatitis B and hepatitis C. Whereas great
apes can be infected with these human viruses, experimentally induced
cases of chimpanzee hepatitis do not seem to progress as frequently to
the complications often seen in humans, such as chronic active
hepatitis, cirrhosis of the liver, and hepatocellular carcinomas
(Muchmore et al., 1988a). Interestingly, as in the case of HIV, there
is evidence suggesting that hepatitis B may actually have originated
from chimpanzees (MacDonald et al. 2000).
Several aspects of female reproductive biology appear to be different
between great apes and humans. Menopause is a natural state in human
females that has not been observed in long-lived captive female
chimpanzees (Graham 1979). Human females are also unusual in typically
having obviously visible breasts in the absence of pregnancy or
lactation, and in having a high frequency of breast diseases
(fibrocystic disease and cancer, in particular). Also, the absence of
external signs of ovulation in human females may result in
fertilization taking place at suboptimal times with regard to the
condition of the ovum. Thus, the question arises whether fertilization
of deteriorating eggs may explain at least partly the high rate
of early fetal wastage in humans that is typically associated with
gross chromosomal and other genetic abnormalities. Regarding
menstruation, anecdotal evidence suggests that the volume of blood lost
per normal cycle might be significantly larger in humans, and that
menometrorrhagia (excessive and frequent bleeding seen particularly in
perimenopausal humans) is not common in great apes. These issues
obviously have significant effects on the health and lifestyle of human
females. Because the other general features of human and chimpanzee
female reproductive biology (e.g., the overall ovarian cycle) are quite
similar, comparative genomics could help unveil the basis for the
unusual human features, each of which has some biomedical implications.
In addition to the above examples, anecdotal evidence suggests that some other common human conditions are rare in great apes in captivity (E. Strobert and B. Swenson, pers. comm.). Despite a high frequency of atopic rhinitis and polyps, bronchial asthma is rarely diagnosed in chimpanzees. Acne vulgaris, a common skin affliction of human teenagers also appears to be uncommon in the adolescent chimpanzee. Another common human disorder that apparently has not been detected in chimpanzees is rheumatoid arthritis. The external physical manifestations of each of these diseases are so obvious that they are very unlikely to have been missed by the experienced veterinarians involved in the long-term care of captive chimpanzees. Of course, one cannot rule out a generally lower sensitivity of caregivers for picking up mild versions of these illnesses in chimps.
Simply sequencing the genome of a chimpanzee and that of an Old World
monkey does not provide a panacea. To emphasize the limitations of
understanding derived from completing a genome sequence, it is hard to
improve upon the statement of Alberts and Klug: "Determining the
sequence of the genome is similar to completing the list of the
chemical elements: it tells us about the basic components, but not
about how they behave in combination. In other words, it gets us to the
starting line for a massive increase in understanding, but does nothing
by itself to provide us with that understanding." (Alberts and Klug
2000). In this regard, we are still sadly lacking in a basic
understanding of much of the biology, biochemistry, cell biology, and
developmental biology of great apes that has been well studied in
humans and in some other vertebrate model systems. Hence, to optimize
the value of a chimpanzee genome project, there needs to be a parallel great ape phenome project (Varki et al. 1998) that would systematically obtain such basic information about the great apes. The current excess
of chimpanzees in NIH-sponsored facilities provides an obvious
opportunity for well-planned, ethically justified, and humane research
that will benefit both humans and great apes. Regarding the hypothesis
that the recent epidemic of breast and ovarian cancer is caused by
evolutionary changes in the reproductive life-styles of westernized
human females (Eaton et al. 1994), the current moratorium on chimpanzee
breeding in NIH-funded facilities represents a comparative experiment
that is already underway.
Assuming that the NIH (perhaps in a consortium with other interested
federal agencies) will soon carry out a chimpanzee/primate genome
project, how can we obtain and analyze the data most effectively? A
recent cataloging of the known genetic differences between humans and
great apes (Gagneux and Varki 2000) indicates that some of the
differences might be quite obvious, that is, new junctions arising from
chromosomal inversions and fusions, gene duplications, nonsense
mutations, exon deletions, and repetitive element insertions. However,
it is possible that some of the critical genetic differences will be
single base pair changes that result in the altered action of a
promoter or a functionally critical amino acid coding difference. Human
genomes seem to vary from each other by about 1 bp/1000 (Ruvolo 1997;
Goodman et al. 1998; Venter et al. 1998; Collins and Jegalian 1999),
and the number is probably about 1 in 250 among chimpanzees (see Box
1). Moreover, the original comparisons of individual human and chimp
genomes showed a range of difference from 1.4 to 2.1%. Thus, obtaining
the complete sequence of a single chimpanzee genome will not be
sufficient to provide all answers. However, such single nucleotide
polymorphisms (SNPs) are currently being catalogued within human
populations for other purposes (Collins and Jegalian 1999). This,
together with the power of PCR- and gene array chip-based approaches
(Hacia et al. 1998, 1999), should make it possible to quickly identify
which SNPs are unique to the chimpanzee or the human. Given how close
chimpanzee are to humans, one could perhaps piggyback the sequencing of
the chimpanzee genome along with the future sequencing of multiple
individual humans to identify human SNPs. Another possible approach
would be to carry out the chimpanzee sequencing by use of a pool of chimpanzee genomes (presumably including representatives from the full
range of known chimpanzee subspecies) (Gagneux et al. 1999) as the
template for PCR-based sequencing. The complete knowledge of the human
genome will make it easy to design the primers for either approach and if a particular primer set does not work, this will point to an
obvious difference between the two genomes. Other approaches might take
advantage of large-scale gene chip-based microarrays (Hacia et al.
1998, 1999)
Of course, only one-half of the differences between the human and
chimpanzee genomes occurred on the way to becoming human the other
half represents changes that occurred in the chimpanzee lineage (Saitou
2000). Thus, to narrow down the differences of interest, all
differences that are found to be universal and unique to either the
human or the chimpanzee should be eventually checked against the
corresponding bonobo and gorilla sequences, to determine the likely
ancestral state. To maximize the value of obtaining the chimpanzee
genome, it would also be important to place the genome of at least one
Old World monkey high on the priority list. This information will help
to further narrow the range of differences that are of interest.
Logical choices would include Macaca mulatta (the rhesus
macaque) and Papiovhamadryas (the baboon), which have been
subjects of much biomedical research over the years. The corollary
benefits to monkeys and to the existing research programs involving
them are obvious.
Last, but not least, the sequencing of the chimpanzee genome can also be considered a moral imperative. Primarily as a consequence of human activities, our closest evolutionary cousins are rapidly dwindling in numbers in the wild, to the point where complete extinction of these populations is a real danger. Meanwhile, the large number of great apes in captivity are being cared for in a less than ideal manner, because the medical approach taken largely assumes that their genes and biology are identical to ours. Better knowledge concerning the genomes and phenomes of these sentient species would be extremely valuable to enhance their care and would further highlight the urgent need for their conservation.
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ACKNOWLEDGMENTS |
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I thank Arno Motulsky, Pascal Gagneux, David Ginsburg, Kurt Benirschke, and Mark Weiss for helpful comments and criticisms, and Elizabeth Strobert, Brent Swenson, and Harold McClure for sharing their long-term experiences at the Yerkes Primate Center.
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FOOTNOTES |
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1 E-MAIL avarki{at}ucsd.edu; FAX (858) 534-5611.
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0.26 SD, range 1.4-2.1) (Sibley and Ahlquist 1987