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Contact
Information
University Of Illinois at Chicago
Dept. Of Biochemistry and
Molecular Genetics
900
S. Ashland (M/C 669)
Chicago, IL 60607
tel: 312-996-7670
fax: 312-413-0353
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| Dr. Alisa L. Katzen |
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katzen@uic.edu
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| Genetic
analysis of cell cycle regulation during development;
the role of a proto-oncogene. During organismal
development, control of the cell cycle is complex
and is a critical component for determining whether
a cell should divide, terminally differentiate,
or die. Because it provides a powerful genetic
and developmental system in which to dissect cellular
and biochemical processes, Drosophila melanogaster
is an attractive model system for studying the
highly conserved biochemical pathways that regulate
cellular division and differentiation during development.As
a tool for understanding these processes, we are
studying the function of Drosophila myb (Dm myb),
a gene related to the proto-oncogene c-myb, which
is a member of a small gene family in vertebrates.
c-myb is thought to normally play an important
role in controlling cell proliferation, and mutant
versions of the gene have been implicated in causing
cancer in chickens, mice, and humans. myb genes
encode sequence-specific DNA-binding proteins
that regulate transcription, but a great deal
remains unknown about how this activity is governed
and which genes are under myb control. |
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Dr. Alisa L. Katzen, Associate Professor
PhD, University of California, San Francisco
Basil O’Connor
Starter Scholar Research Award
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Elucidating the function of Drosophila myb and uncovering
the signal transduction pathway(s) in which it participates
will help us to understand regulation of the cell cycle
during development and provide insights into how mutant
versions of the gene cause uncontrolled cell growth.
Using classical genetic screens, we generated two mutant
alleles of Dm myb. Each contains a single base pair
substitution resulting in the change of an amino acid
perfectly conserved between Dm myb and its vertebrate
counterparts. Examination of mutant phenotypes showed
that Dm myb is important for both embryonic and adult
development and that myb serves a role in the development
of many tissues. Detailed analysis of the wing phenotype
revealed that mutant wings contain approximately half
the number of cells in wild type, and that the defect
occurs during the final cell cycle. Mutant wing cells
enter S-phase but are blocked before mitosis, with some
of the cells beginning to endoreplicate their DNA. These
results indicate that Dm myb is required for progression
through the G2/M transition and for maintenance of diploidy.
Recent studies of the abdominal phenotype have revealed
additional roles for Dm myb in the cell cycle. The mutant
cells proliferate slowly and abnormal mitoses associated
with multiple functional centrosomes, unequal chromosome
segregation, formation of micronuclei, and/or failure
to complete cell division are observed (see Figure 1).
These findings demonstrate that in abdominal epidermal
cells, Dm myb is required to sustain the appropriate
rate of proliferation, to suppress formation of supernumerary
centrosomes, and to maintain genomic integrity.
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Figure 1. Abnormal mitoses
are observed in abdominal epidermal cells that are mutant
for myb.
Abdominal epidermal samples from wild type (panel A) and
myb2 mutants were triply stained to visualize nuclei (blue),
microtubules (green), and red (centrosomes).
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| We have also generated
transgenic animals in which we can induce ectopic expression
of wild type and mutant versions of Dm myb. We have found
that ectopic expression of Dm myb within the developing
animal can have potent consequences, including inducing
pattern disruption and even lethality. Ectopic expression
of Dm myb can have opposing effects on cell cycle regulation,
promoting proliferation in diploid cells (Figure 2), but
suppressing endoreduplication in polyploid tissues (Figure
3). Therefore, we conclude that DMyb functions in multiple
aspects of the cell division cycle to promote proliferation
and maintain the integrity of the genome. A schematic
is shown in Figure 4. |
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Figure 2. Ectopic
expression of DMyb promotes S-phase in the ZNC of larval
wing discs.
Wing discs that were doubly stained to visualize nuclei
(left panels) and for DNA synthesis by BrdU incorporation
(right panels). (A) In wild type control discs, BrdU incorporation
was not detected in the zone of non-proliferating cells
(ZNC), which is composed of cells at the dorsoventral
boundary (see arrowheads). (B) However, when DMyb is ectopically
expressed in the posterior compartment of the disc (right
side of the disc), BrdU incorporation could be detected
in the posterior ZNC (indicated by arrow). |
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Figure
3. Ectopic DMyb activity inhibits endoreduplication
and growth in salivary glands.
Salivary glands were stained with DAPI to visualize
nuclei. Salivary glands dissected from wild type larvae
(A) were considerably larger than those dissected from
larvae in which an activated form of DMyb had been ectopically
expressed (B). In the right panels, a representative
nucleus from each salivary gland is shown at higher
magnification. |
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Figure 4.
Schematic representation of the multiple roles DMyb
plays in regulating the mitotic and endoreplicative
cell cycles.
DMyb is a positive regulator of both progression from
G1 into S-phase and G2 into mitosis, but is a negative
regulator of endoreplication, indicating that it plays
an important role maintaining diploidy and preserving
genomic integrity. |
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Our laboratory continues to pursue research that will
help us to: 1) gain further understanding of myb function
in regulating the cell cycle and differentiation during
Drosophila development; 2) identify genes that participate
in the same signal transduction pathway(s) as myb through
genetic approaches; and 3) address the functional relationship
between Drosophila myb and its vertebrate counterparts. |
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Selected Publications:
Katzen, A. L. “Drosophila Myb:
lessons for the understanding of vertebrate Myb proteins”
in Myb Transcription Factors: Their Role in Growth,
Differentiation and Disease, edited by Jonathan
Frampton (Kluwer Academic Publishers B.V.). In Press.
Fuse, N., K. Hisata, K., A. L. Katzen,
F. Matsuzaki. (2003). Heterotrimeric G proteins regulate
cell size asymmetry in Drosophila neuroblast divisions.
Curr Biol. 13, 947-954.
Fung, S-M., G. Ramsay, and A. L. Katzen.
(2003). Myb and CBP: Physiological relevance of a biochemical
interaction. Mech. Dev. 120, 711-720. (pdf)
Sharkov, N. V., G. Ramsay, and A. L. Katzen.
(2002). The DNA replication-related element-binding
factor (DREF) is a transcriptional regulator of the
Drosophila myb gene. Gene 297, 209-219. (pdf)
Fitzpatrick, C. A., N. V. Sharkov, G. Ramsay, and A.
L. Katzen. (2002). Drosophila myb exerts opposing
effects on S-phase, promoting proliferation and suppressing
endoreduplication. Development 129, 4497-4507. (pdf)
Fung, S-M., G. Ramsay, and A.L. Katzen.
(2002) Mutations in Drosophila myb lead to centrosome
amplification and genomic instability. Development 129,
347-359. (pdf)
Jackson, J., N.V. Sharkov, E. Lium, G. Ramsay, and
A.L. Katzen. (2001). The role of transcriptional
activation in the function of the Drosophila myb gene.
Blood Cells, Molecules, and Diseases 27:446-455. (pdf)
Katzen, A. L., J. Jackson, B. P. Harmon,
S-M. Fung, G. Ramsay and J. M. Bishop. (1998). Drosophila
myb is required for the G2/M transition and maintenance
of diploidy. Genes Dev. 12, 831-843. (pdf)
Katzen, A.L. and J.M. Bishop. (1996).
myb provides an essential function during Drosophila
development. Proc. Natl. Acad. Sci. USA 93,13955-13960.
(pdf)
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© 2007 University of Illinois at Chicago
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