Thomas Blumenthal, Ph.D.
Professor and Chair, Department of Biology-MCD Instruction
Professor of Biochemistry & Molecular Genetics
Department of Biology
University of Colorado at Boulder
347 UCB
Boulder, Colorado 80309-0347
Office Phone: 303.492-7533
tom.blumenthal@uchsc.edu
EDUCATION/EXPERIENCE
HONORS AND AWARDS
PROFESSIONAL ACTIVITIES
LAB PERSONNEL
Research Interests
Splicing, Gene Structure
and Chromosome Architecture in C. Elegans
My laboratory works on the small nematode worm, C. elegans, as a
model to understand gene regulation and expression in higher animals.
In the process of studying mechanisms of mRNA splicing in C. elegans,
our laboratory has discovered that a significant proportion of genes
in this animal are arranged and transcribed in a manner quite similar
to bacterial operons. This is very unusual in eukaryotes and previously
unheard of in animals. The polycistronic pre-mRNAs are converted
into monocistronic units by cleavage and polyadenylation and by
trans-splicing. We are interested in three general questions. 1)
What mechanisms are involved in processing of the polycistronic
mRNAs? 2) Do the C. elegans operons serve the purpose of co-regulating
genes whose products function together, as operons do in bacteria?
and 3) How and when did operons arise during eukaryotic evolution?
Like genes in other animals, C. elegans genes contain introns that
are spliced out by spliceosomes. However, C. elegans has another
type of splicing, mechanistically quite similar to removal of introns,
called trans-splicing, in which a short leader is spliced onto the
5' ends of mRNAs. Recognition of a trans-splice site requires only
that the pre-mRNA have a 3' splice site with no upstream 5' splice
site. Although, C. elegans has two spliced leaders, SL1 and SL2,
only SL1 is utilized in such situations. SL2 is reserved for genes
located in downstream positions in operons. There is a close connection
between formation of the 3' end of the upstream gene and trans-splicing
about 100 nucleotides downstream at the 5' end of the next gene
in the polycistronic pre-mRNA. Current efforts are directed towards
understanding the nature of this connection.
We are also studying splice-site recognition in C. elegans, since
it appears to be somewhat different from other animals, perhaps
because the splicing machinery must cope with both cis-splicing
and two kinds of trans-splicing (SL1 and SL2). We have cloned the
genes that encode the two subunits of the splicing factor U2AF,
which is involved in splice acceptor site recognition. We have discovered
that both U2AF subunits interact with the 3' splice site consensus
sequence, with the small subunit responsible for recognition of
the invariant AG/R at the splice junction. The pre-mRNA that encodes
the large subunit of U2AF is alternatively spliced, which may represent
a mechanism for autogenous regulation of U2AF levels.
Selected Publications
- MacMorris, M. A., D. A. R. Zorio and T. Blumenthal.
1999. An exon that prevents transport of a mature mRNA. Proc.
Natl. Acad. Sci. USA: 96, 3813-3818.[Abstract]
- Zorio, D. A. R. and T. Blumenthal. 1999. Both
subunits of U2AF recognize 3' splice sites inCaenorhabditis elegans.
Nature 402, 835-838.[Abstract]
- Evans, D. and T. Blumenthal. 2000. Trans-splicing
of polycistronic Caenorhabditis elegans pre-mRNAs: analysis of
the SL2 RNA. Mol. Cell. Biol. 20, 6659-6667.[Abstract]
- Liu, Y. Huang, T., MacMorris, M. and T, Blumenthal.
2001. Interplay between AAUAAA and the trans-splice site in processing
of a Caenorhabditis elegans operon pre-mRNA. RNA 7, 176-181.[Abstract]
- Huang, T., S. Kuersten, A. M. Deshpande, J.
Spieth, M. MacMorris and T. Blumenthal. 2001. An intercistronic
region required for polycistronic pre-mRNA processing in Caenorhabditis
elegans. Mol. Cell. Biol. 21, 1111-1120.[Abstract]
- Evans, D., I. Perez, M. MacMorris, D. Leake,
C. J. Wilusz and T. Blumenthal. 2001. A complex containing CstF
and the SL2 snRNP connects mRNA 3' end formation and trans-splicing
in Caenorhabditis elegans operons. Genes and Dev. In press [Abstract]
Bibliography
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