Research
Interests of Dr. Richard H. Finnell
Research
in Dr. Finnell's laboratory focuses on the interaction between
specific genes and environmental toxicants as they influence
normal embryonic development. The laboratory currently has
four major research areas, all of which focus on determining
susceptibility to environmentally induced birth defects.
These four areas are summarized below.
Knockout
and transgenic animal development to study the role of folic
acid in the prevention of birth defects. We have used homologous
recombination in embryonic stem cell technology in order
to successfully knockout both of the murine folate binding
protein genes (Folbp1 and Folbp2), as well as the reduced
folate carrier gene (RFC1). The heterozygous Folbp1 animals
have significantly lower serum folic acid levels and very
high serum and brain homocysteine levels when the dams are
maintained on a low folate diet. Embryos homozygous for the
Folbp1 null allele fail to develop beyond gestational day
10, and these embryos all have neural tube defects (NTDs)
and other serious congenital malformations. When the Folbp1
heterozygous dams are on placed on folate supplementation,
we are able to rescue the phenotype and have observed grossly
normal nullizygous gestational day 18 fetuses or, if provided
lesser levels of supplementation, the nullizygous embryos
have craniofacial and/or conotruncal heart defects. When
the pups are delivered and the dams supplemented with folic
acid during the weaning period, the nullizygotes survive
into adulthood. While supplemental folic acid has been shown
to reduce the risk for NTDs and other congenital malformations
in humans, the mechanisms underlying this protective effect
are unknown. Utilizing the knockout animals will help us
to learn more about this phenomenon on both molecular and
morphological levels. To this end, we are currently manipulating
folic acid and homocysteine concentrations in the dams and
the embryos by dietary means and then using cDNA microarray
technology in order to identify which gene or genetic pathways
are critical to the regulation of this response. We have
also examined embryos that lack a functional folate transporter
protein (RFC1). These knockout nullizygotes also lethal in
utero, as the embryos have devastating congenital malformations.
We are working on a rescue paradigm so that we have more
fully developed embryos to study. When we make the compound
heterozygotes, we will have embryos that have been compromised
in their ability to bind folates, internalize them, and transport
them intracellularly. We are also working on a high-throughput
screening system in order to determine the relative importance
of enhancer and regulatory regions of these genes as they
impact susceptibility to selected birth defects.
Candidate
genes for susceptibility to human neural tube defects (NTDs)
and orofacial clefts. My laboratory serves as the mutation
analysis laboratory for the States of California and Texas
in support of their participation in the National Birth Defects
Prevention Study. These are two of the eight CDC recognized
Centers of Excellence. We use a variety of mutation analysis
approaches to screen population based case-control samples
for polymorphisms in several different candidate genes to
identify significant gene-environment interactions. Many
of these samples are stratified as to the vitamin status
of the mother to enable us to focus in on various hypotheses
concerning folates and birth defects. It has been shown in
human epidemiological studies that certain populations fail
to benefit from folate supplementation. Our hypothesis is
that individuals with mutant folate receptors or transporter
genes are less capable of binding both dietary and/or supplemental
folic acid for transport to the placenta and harvest by the
fetus during critical periods of neural tube closure, resulting
in NTDs. We are currently testing this hypothesis examining
the gene coding for the 5-methyltetrahydrofolate receptor
(hFRa) as well as MTHFR, MTHFD, NAT1, NAT2, SHH, MTRR, PDGFR,
BHMT, BHMT2, MS, and RFC1, using dideoxy-DNA fingerprinting
and single strand conformational polymorphism analysis to
screen the samples in a high-throughput manner as well as
direct sequencing when indicated. We have also examined genes
related to energy metabolism (UPC2), obesity (leptin and
its receptor), and drug metabolism (mEH, GST). We are also
interested in testing the hypothesis that homocysteine acts
as an NMDA receptor antagonist which disrupts normal cardiac
and neural tube development. We will examine the folate pathway
genes in patients exposed in utero to a variety of pharmaceutical
and environmental samples that can interfere with normal
homocysteine remethylation. As an adjunction to these molecular
epidemiology studies, the laboratory is actively cloning
new human folate receptor and transporter genes that might
serve as new targets for these epidemiological investigations.
Antiepileptic
drug therapy and congenital malformations. The laboratory
has a long-standing interest in the teratogenicity of anticonvulsant
medications. Using animals models, we are trying to identify
specific alterations in gene expression and function that
can explain the craniofacial dysmorphia observed in human
infants exposed in utero to phenytoin. We have observed this
drug to act as a retinoic acid agonist, and increase the
binding of the retinoic acid receptors. It is possible that
the craniofacial defects could be related to altered expression
of the retinoic acid receptors and RAREs (retinoic acid response
elements) regulating downstream growth factors. Efforts are
underway to characterize the functional significance of a
truncated RARa transcript observed in target tissues following
in utero exposure to teratogenic concentrations of phenytoin.
In another series of experiments, we have we have finally
established solid linkage with a gene that confers susceptibility
to anti-epileptic drug induced NTDs. We are in the process
of positionally cloning this gene and learning more about
its characteristics. We are working with a critical region
of less than one cM, and will soon receive a recombinant
inbred mouse line derived from C57BL/6J and A/J mice from
Dr. Joseph Nadeau, which should help use to further resolve
the critical region. Once the mouse gene is positionally
cloned, we will clone its human ortholog and then examine
the clinical samples that have been collected which include
sibships with both adverse and normal pregnancy outcomes
in the face of maternal anticonvulsant drug therapy during
pregnancy.
Environmental
Toxicogenetics. The final area in which we work combines
many aspects of the above-mentioned studies yet focuses the
technology on addressing problems of true environmental significance.
Funded through the Superfund Research Program, we are working
with a variety of investigators at Texas A&M University
to study the consequences of complex mixtures and petrochemical
pollution on birth defects using both genetically modified
mouse model systems and human molecular epidemiology studies.
The mouse work involves test compounds (arsenic, TCDD, BAP)
and embryos that should be genetically sensitive (Folbp1)
or resistant (AhR-) to these exogenous agents. We will define
the responses on both the morphological and molecular levels,
using genetic microarray technology. In parallel, we are
establishing the infrastructure to perform molecular epidemiology
studies in the petrochemical producing country, Azerbaijan,
which has very high anecdotal rates of congenital defects.
Representative
Publications
Spiegelstein,
O., Lu, X., Le, X.C., Troen, A., Selhub, J.,Melnyk, S., James,
S.J. and Finnell, R.H. 2005. Effects of dietary
folate intake and folate binding protein 2 (Folbp2) on urinary
speciation of sodium arsenate in mice. Env. Toxicol. & Pharmacol.
19:1-7.
Birn, H., Spiegelstein, O., Christensen, E.I. and Finnell,
R.H. 2005. Renal tubular reabsorption of folate mediated by
folate binding protein 1. Am.J.Soc. Nephrol. 16:608-615.
Moretti, P., Sahoo, T., Hyland, K., Bottiglieri, T., Del Gaudio,
D., Roa, B., Curry, S., Zhu, H., Finnell, R.H., Neul, J., Ramaekers,
V.T., Blau, N., Bacino, C., Miller, G. and Scaglia, F. 2005.
Cerebral folate deficiency with features of Angelman syndrome
and response to folinic acid. Neurology. 64(6):1088-90.
Zhu, H., Curry, S., Wen, S., Shaw, G.M., Lammer, E.J., Wicker,
N., Yang, W., Jafarov, T., and Finnell, R.H. 2005. Are the
betaine-homocysteine methyltransferase (BHMT and BHMT2) genes
risk factors for spina bifida and orofacial clefts? Am. J.
Med. Genet. 135(3):274-277.
Ma, D., Finnell, R.H., Davidson, L.A., Callaway, E.S., Spiegelstein,
O., Piedrahita, J.A., Salbaum, J.M., Kappen, C., Weeks, B.,
James, S.J., Bozinov, D., Lupton, J.R., and Chapkin, R.S. 2005.
Folate transport gene inactivation in mice increases sensitivity
to colon carcinogenesis. Cancer Res. 65:887-897.
Olshan, A.F., Shaw, G.M., Millikan, R.C., Laurent, C. and
Finnell, R.H. 2005. Polymorphisms in DNA repair genes as risk
factors for spina bifida and orofacial clefts. Am. J. Med.
Genet. 135(3):268-273.
Pei, L., Zhu, H., Ren, A., Li, Z. Hao, L., Finnell, R.H. and
Zhu, L. 2005. Reduced folate carrier gene is a risk factor
for neural tube defects in a Chinese Population. Birth Defects
Res A. 73:430-433. Zhu, H., Lu, W., Laurent, C., Shaw, G.M., Lammer, E.J., and
Finnell, R.H. 2005. Genes Encoding Catalytic Subunits of Protein
Kinase A and Risk of Spina Bifida. Birth Defects Research A.
73:591-596.
Jafarov, T., Zhu, H., Finnell, R. and Kulieva, S. 2005. Epidemiologic
study on HFE C282Y mutation in Azerbaijan. Eur. J. Haematol.
74:180-181.
Tang,
L.S., Santillano, D.R., Miranda, R.C. and Finnell, R.H. 2005.
Role of Folbp1 in the regional regulation of apoptosis
and cell proliferation in the developing neural tube and craniofacies.
Am J Med Genet C Semin Med Genet. 135(1):48-58.
Shaw, G.M., Carmichael, S.L., Yang, W., Harris, J.A., Finnell,
R.H. and Lammer, E.J., 2005. Epidemiologic characteristics
of anophthalmia and bilateral microphthalmia among 2.5 million
births in California,
1989-1997. Am. J. Med. Genet. 137:36-40.
Shaw, G.M., Iovannisci, D.M, Yang, W., Finnell, R.H., Carmichael,
S.L., Cheng, S., and Lammer, E.J. 2005. Risks of human conotruncal
heart defects associated with 32 single nucleotide polymorphisms
of selected cardiovascular disease-related genes. Am. J. Med.
Genet. 138:21-26.
Blanton, S.H., Cortez, A., Stal, S., Mulliken, J.B., Finnell,
R.H., and Hecht, J.T. 2005. Variation in IRF6 contributes to
nonsyndromic cleft lip and palate. Am. J. Med. Genet. 137:259-262.
Lammer, E.J., Shaw, G.M., Iovannisci, D.M. and Finnell, R.H.
2005. Maternal smoking, genetic variation of glutathione s-transferases,
and risk of orofacial clefts. Epidemiology 16:698-701.
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