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3. E2F4’s cytoplasmic role in multiciliogenesis is mediated via an N-terminal domain that binds two components of the centriole replication machinery, Deup1 and SAS6

Author

Massachusetts Institute of Technology. Department of Biology, Hazan, Renin, Mori, Munemasa, Danielian, Paul S, Guen, Vincent J, Rubin, Seth M, Cardoso, Wellington V, Lees, Jacqueline A, Massachusetts Institute of Technology. Department of Biology, Hazan, Renin, Mori, Munemasa, Danielian, Paul S, Guen, Vincent J, Rubin, Seth M, Cardoso, Wellington V, and Lees, Jacqueline A

Abstract

Multiciliogenesis requires both nuclear and cytoplasmic functions of the E2F4 transcription factor. Here we identify a domain in E2F4 that interacts with two key components of the cytoplasmic centriole replication machinery, Deup1 and SAS6, and is sufficient to mediate E2F4’s cytoplasmic role in multiciliogenesis.

Published
2022

11. Rb regulates fate choice and lineage commitment in vivo

Author

Calo, Eliezer, Quintero-Estades, Jose A., Danielian, Paul S., Nedelcu, Simona, Berman, Seth D., and Lees, Jacqueline A.

Subjects
Oncology, Experimental, Mutation (Biology) -- Health aspects, Tumor suppressor genes -- Research, Transcription factors -- Health aspects, Cancer -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Rb suppressor and cell fate The tumour suppressor Rb (retinoblastoma protein) is mutated in about one-third of human tumours. It suppresses the activity of certain transcription factors and potentiates the activity of others, and has been shown to affect the differentiation of different cell lineages in vitro. Jacqueline Lees and colleagues now show that Rb plays a role in determining fate choice between bone cell and brown adipose tissue formation in vivo in mouse osteosarcoma models, acting via the bone and fat master regulators Runx2 and PPAR[gamma] The retinoblastoma tumour suppressor protein pRb can suppress the activity of certain transcription factors and potentiate the activity of others, and has been shown to affect the differentiation of different cell lineages in vitro. These authors show that the Rb gene has a role in driving bone cell formation or brown adipose tissue formation in vivo. Mutation of the retinoblastoma gene (RB1) tumour suppressor occurs in one-third of all human tumours and is particularly associated with retinoblastoma and osteosarcoma.sup.1. Numerous functions have been ascribed to the product of the human RB1 gene, the retinoblastoma protein (pRb). The best known is pRb's ability to promote cell-cycle exit through inhibition of the E2F transcription factors and the transcriptional repression of genes encoding cell-cycle regulators.sup.1. In addition, pRb has been shown in vitro to regulate several transcription factors that are master differentiation inducers.sup.2. Depending on the differentiation factor and cellular context, pRb can either suppress or promote their transcriptional activity. For example, pRb binds to Runx2 and potentiates its ability to promote osteogenic differentiation in vitro.sup.3. In contrast, pRb acts with E2F to suppress peroxisome proliferator-activated receptor [gamma] subunit (PPAR-[gamma]), the master activator of adipogenesis.sup.4,5. Because osteoblasts and adipocytes can both arise from mesenchymal stem cells, these observations suggest that pRb might play a role in the choice between these two fates. However, so far, there is no evidence for this in vivo. Here we use mouse models to address this hypothesis in mesenchymal tissue development and tumorigenesis. Our data show that Rb status plays a key role in establishing fate choice between bone and brown adipose tissue in vivo., Author(s): Eliezer Calo [sup.1] , Jose A. Quintero-Estades [sup.1] , Paul S. Danielian [sup.1] , Simona Nedelcu [sup.1] , Seth D. Berman [sup.1] , Jacqueline A. Lees [sup.1] Author Affiliations: [...]

Published
2010
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12. Cytoplasmic E2f4 forms organizing centres for initiation of centriole amplification during multiciliogenesis

Author

Koch Institute for Integrative Cancer Research at MIT, Hazan, Renin, Danielian, Paul S, Miller, Emily Sun Young, Lees, Jacqueline, Mori, Munemasa, Mahoney, John E., Li, Huijun, Lu, Jining, Zhu, Xueliang, Cardoso, Wellington V., Danielian, Paul S., Koch Institute for Integrative Cancer Research at MIT, Hazan, Renin, Danielian, Paul S, Miller, Emily Sun Young, Lees, Jacqueline, Mori, Munemasa, Mahoney, John E., Li, Huijun, Lu, Jining, Zhu, Xueliang, Cardoso, Wellington V., and Danielian, Paul S.

Abstract

Abnormal development of multiciliated cells is a hallmark of a variety of human conditions associated with chronic airway diseases, hydrocephalus and infertility. Multiciliogenesis requires both activation of a specialized transcriptional program and assembly of cytoplasmic structures for large-scale centriole amplification that generates basal bodies. It remains unclear, however, what mechanism initiates formation of these multiprotein complexes in epithelial progenitors. Here we show that this is triggered by nucleocytoplasmic translocation of the transcription factor E2f4. After inducing a transcriptional program of centriole biogenesis, E2f4 forms apical cytoplasmic organizing centres for assembly and nucleation of deuterosomes. Using genetically altered mice and E2F4 mutant proteins we demonstrate that centriole amplification is crucially dependent on these organizing centres and that, without cytoplasmic E2f4, deuterosomes are not assembled, halting multiciliogenesis. Thus, E2f4 integrates nuclear and previously unsuspected cytoplasmic events of centriole amplification, providing new perspectives for the understanding of normal ciliogenesis, ciliopathies and cancer., National Institutes of Health (U.S.) (Grant PO1-CA42063), National Cancer Institute (U.S.) (Grant PO1-CA42063), National Institutes of Health (U.S.) (Grant P30-CA14051), National Cancer Institute (U.S.) (Grant P30-CA14051)

Published
2018

13. E2f4 is required for normal development of the airway epithelium

Author

Danielian, Paul S., Kim, Carla F. Bender, Caron, Alicia M., Vasile, Eliza, Bronson, Roderick T., and Lees, Jacqueline A.

Subjects
Epithelium, Biological sciences
Abstract

To link to full-text access for this article, visit this link: http://dx.doi.org/10.1016/j.ydbio.2007.02.037 Byline: Paul S. Danielian (a), Carla F. Bender Kim (b), Alicia M. Caron (a), Eliza Vasile (a), Roderick T. Bronson (c), Jacqueline A. Lees (a) Keywords: E2f4; Epithelium; Nasal; Respiratory; Ciliated; Goblet; Clara cells; Mucin Abstract: The airway epithelium is comprised of specialized cell types that play key roles in protecting the lungs from environmental insults. The cellular composition of the murine respiratory epithelium is established during development and different cell types populate specific regions along the airway. Here we show that E2f4-deficiency leads to an absence of ciliated cells from the entire airway epithelium and the epithelium of the submucosal glands in the paranasal sinuses. This defect is particularly striking in the nasal epithelium of E2f4-/- mice where ciliated cells are replaced by columnar secretory cells that produce mucin-like substances. In addition, in the proximal lung, E2f4 loss causes a reduction in Clara cell marker expression indicating that Clara cell development is also affected. These defects arise during embryogenesis and, in the nasal epithelium, appear to be independent of any changes in cell proliferation, the principal process regulated by members of the E2f family of transcription factors. We therefore conclude that E2f4 is required to determine the appropriate development of the airway epithelium. Importantly, the combination of no ciliated cells and excess mucous cells can account for the chronic rhinitis and increased susceptibility to opportunistic infections that causes the postnatal lethality of E2f4 mutant mice. Author Affiliation: (a) Center for Cancer Research, Massachusetts Institute of Technology, 77 Massachusetts Avenue, Cambridge, MA 02139, USA (b) Stem Cell Program, Children's Hospital, Harvard Stem Cell Institute, Boston, MA 02115, USA (c) Tufts Cummings School of Veterinary Medicine, North Grafton, MA 01536, USA Article History: Received 29 August 2006; Revised 24 February 2007; Accepted 27 February 2007

Published
2007

14. DTL/CDT2 is essential for CDT1 regulation and the early G2/M checkpoint

Author

Sansam, Christopher L., Shepard, Jennifer L., Lai, Kevin, Ianari, Alessandra, Danielian, Paul S., Amsterdam, Adam, Hopkins, Nancy, and Lees, Jacqueline A.

Subjects
DNA replication -- Research, DNA damage -- Research, Cell cycle -- Research, Biological sciences
Abstract

A study reports that DTL is required for the early, radiation induced G2/M checkpoint in both zebrafish and human cells. It is proposed that a CUL4-DDB1-DTL complex ubiquitinates another key cell cycle regulator in G2 as part of the activation of the G2/M checkpoint.

Published
2006

15. E2f4 and E2f5 are essential for the development of the male reproductive system

Author

Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S, Lees, Jacqueline, Hess, Rex A., Danielian, Paul S., Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S, Lees, Jacqueline, Hess, Rex A., and Danielian, Paul S.

Abstract

The E2F transcription factors are primarily implicated in the regulation of entry and exit from the cell cycle. However, in vivo studies have established additional roles for E2Fs during organ development and homeostasis. With the goal of addressing the intestinal requirements of E2f4 and E2f5, we crossed mice carrying Vil-cre, E2f4 conditional and E2f5 germline alleles. E2f4 deletion had no detectable effect on intestinal development. However, E2f4f/f;E2f5+/−;Vil-cre males, but not E2f4f/f;Vil-cre littermates, were unexpectedly sterile. This defect was not due to defective spermatogenesis. Instead, the seminiferous tubules and rete testes showed significant dilation, and spermatozoa accumulated aberrantly in the rete testis and efferent ducts. Our data show that these problems result from defective efferent ducts, a tissue whose primary function is to concentrate sperm through fluid absorption. First, Vil-cre expression, and consequent E2F4 loss, was specific to the efferent ducts and not other reproductive tract tissues. Second, the E2f4f/f;E2f5+/−;Vil-cre efferent ducts had completely lost multiciliated cells and greatly reduced levels of critical absorptive cell proteins: aquaporin1, a water channel protein, and clusterin, an endocytic marker. Collectively, the observed testis phenotypes suggest a fluid flux defect. Remarkably, we observed rete testis dilation prior to the normal time of seminiferous fluid production, arguing that the efferent duct defects promote excessive secretory activity within the reproductive tract. Finally, we also detect key aspects of these testis defects in E2f5−/− mice. Thus, we conclude that E2f4 and E2f5 display overlapping roles in controlling the normal development of the male reproductive system., National Institutes of Health (U.S.) (Grant NIH-P01 CA42063)

Published
2017

16. A 5.5-kb enhancer is both necessary and sufficient for regulation of Wnt-1 transcription in vivo

Author

Danielian, Paul S., Echelard, Yann, Vassileva, Galya, and McMahon, Andrew P.

Subjects
Central nervous system -- Research, Genetically modified mice -- Analysis, Mesencephalon -- Research, Embryology -- Research, Biological sciences
Abstract

Writ-1 encodes a secreted signaling molecule which is required for development of the midbrain and anterior hindbrain in the mouse. Wnt-1 expression is initiated early in the development of the central nervous system in a region predicted to give rise to the midbrain. Later in development Wnt-1 expression is restricted to regions of the forebrain, midbrain, and spinal cord. Previous studies identified a 5.5-kb enhancer in the Wnt-1 locus which is sufficient to activate transcription of a reporter gene in a pattern very similar to that of the endogenous Wnt-1 gene. Here we have assessed if this enhancer is an important component of the endogenous regulatory sequences of Wnt-1 by gene targeting and by testing if it is able to express Wnt-1 in a pattern which is sufficient to rescue the phenotype of loss of Wnt-1. Our results show that the 5.5-kb enhancer is both necessary and sufficient for Wnt-1 expression in vivo.

Published
1997

19. A vertebrate gene, ticrr, is an essential checkpoint and replication regulator

Author

Sansam, Christopher L., Cruz, Nelly M., Danielian, Paul S., Amsterdam, Adam, Lau, Melissa L., Hopkins, Nancy, and Lees, Jacqueline A.

Subjects
Genetic regulation -- Analysis, Vertebrates -- Genetic aspects, DNA replication -- Research, Chromatin -- Structure, Chromatin -- Chemical properties, Ubiquitin-proteasome system -- Usage, Biological sciences
Published
2010

20. Proteomic analysis of pRb loss highlights a signature of decreased mitochondrial oxidative phosphorylation

Author

Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S., Lees, Jacqueline, Nicolay, Brandon N., Kottakis, Filippos, Lapek, John D., Sanidas, Ioannis, Miles, Wayne O., Dehnad, Mantre, Gierut, Jessica J., Manning, Amity L., Morris, Robert, Haigis, Kevin, Bardeesy, Nabeel, Haas, Wilhelm, Dyson, Nicholas J., Lees, Jacquelineb, Tschop, Katrin, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S., Lees, Jacqueline, Nicolay, Brandon N., Kottakis, Filippos, Lapek, John D., Sanidas, Ioannis, Miles, Wayne O., Dehnad, Mantre, Gierut, Jessica J., Manning, Amity L., Morris, Robert, Haigis, Kevin, Bardeesy, Nabeel, Haas, Wilhelm, Dyson, Nicholas J., Lees, Jacquelineb, and Tschop, Katrin

Abstract

The retinoblastoma tumor suppressor (pRb) protein associates with chromatin and regulates gene expression. Numerous studies have identified Rb-dependent RNA signatures, but the proteomic effects of Rb loss are largely unexplored. We acutely ablated Rb in adult mice and conducted a quantitative analysis of RNA and proteomic changes in the colon and lungs, where Rb[superscript KO] was sufficient or insufficient to induce ectopic proliferation, respectively. As expected, Rb[superscript KO] caused similar increases in classic pRb/E2F-regulated transcripts in both tissues, but, unexpectedly, their protein products increased only in the colon, consistent with its increased proliferative index. Thus, these protein changes induced by Rb loss are coupled with proliferation but uncoupled from transcription. The proteomic changes in common between Rb[superscript KO] tissues showed a striking decrease in proteins with mitochondrial functions. Accordingly, RB1 inactivation in human cells decreased both mitochondrial mass and oxidative phosphorylation (OXPHOS) function. Rb[superscript KO] cells showed decreased mitochondrial respiratory capacity and the accumulation of hypopolarized mitochondria. Additionally, RB/Rb loss altered mitochondrial pyruvate oxidation from [superscript 13]C-glucose through the TCA cycle in mouse tissues and cultured cells. Consequently, Rb[superscript KO] cells have an enhanced sensitivity to mitochondrial stress conditions. In summary, proteomic analyses provide a new perspective on Rb/RB1 mutation, highlighting the importance of pRb for mitochondrial function and suggesting vulnerabilities for treatment., National Institutes of Health (U.S.) (2-P01-CA42063)

Published
2016

21. Abstract IA15: The consequences of pRb inactivation: insights from a proteomic analysis of Rb loss

Author

Nicolay, Brandon N., primary, Danielian, Paul S., additional, Kottakis, Filippos, additional, Lapek, John D., additional, Sanidas, Ioannis, additional, Miles, Wayne O., additional, Dehnad, Mantre, additional, Tschöp, Katrin, additional, Gierut, Jessica J., additional, Manning, Amity L., additional, Morris, Robert, additional, Haigis, Kevin, additional, Bardeesy, Nabeel, additional, Lees, Jacqueline A., additional, Haas, Wilhelm, additional, and Dyson, Nicholas J., additional

Published
2016
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23. Loss of pRB and p107 disrupts cartilage development and promotes enchondroma formation

Author

Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S., Lees, Jacqueline, Landman, A. S., Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S., Lees, Jacqueline, and Landman, A. S.

Abstract

The pocket proteins pRB, p107 and p130 have established roles in regulating the cell cycle through the control of E2F activity. The pocket proteins regulate differentiation of a number of tissues in both cell cycle-dependent and -independent manners. Prior studies showed that mutation of p107 and p130 in the mouse leads to defects in cartilage development during endochondral ossification, the process by which long bones form. Despite evidence of a role for pRB in osteoblast differentiation, it is unknown whether it functions during cartilage development. Here, we show that mutation of Rb in the early mesenchyme of p107-mutant mice results in severe cartilage defects in the growth plates of long bones. This is attributable to inappropriate chondrocyte proliferation that persists after birth and leads to the formation of enchondromas in the growth plates as early as 8 weeks of age. Genetic crosses show that development of these tumorigenic lesions is E2f3 dependent. These results reveal an overlapping role for pRB and p107 in cartilage development, endochondral ossification and enchondroma formation that reflects their coordination of cell-cycle exit at appropriate developmental stages., Virginia and D.K. Ludwig Fund for Cancer Research (Fellowship), National Cancer Institute (U.S.) (Grant CA121921)

Published
2015

24. Proteomic analysis of pRb loss highlights a signature of decreased mitochondrial oxidative phosphorylation

Author

Nicolay, Brandon N., primary, Danielian, Paul S., additional, Kottakis, Filippos, additional, Lapek, John D., additional, Sanidas, Ioannis, additional, Miles, Wayne O., additional, Dehnad, Mantre, additional, Tschöp, Katrin, additional, Gierut, Jessica J., additional, Manning, Amity L., additional, Morris, Robert, additional, Haigis, Kevin, additional, Bardeesy, Nabeel, additional, Lees, Jacqueline A., additional, Haas, Wilhelm, additional, and Dyson, Nicholas J., additional

Published
2015
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26. E2F4 cooperates with pRB in the development of extra-embryonic tissues

Author

Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Lee, Eunice Y., Yuan, Tina L., Danielian, Paul S., West, Julie C., Lees, Jacqueline, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Lee, Eunice Y., Yuan, Tina L., Danielian, Paul S., West, Julie C., and Lees, Jacqueline

Abstract

August 1, 2010, The retinoblastoma gene, RB-1, was the first identified tumor suppressor. Rb[superscript −/−] mice die in mid-gestation with defects in proliferation, differentiation and apoptosis. The activating E2F transcription factors, E2F1–3, contribute to these embryonic defects, indicating that they are key downstream targets of the retinoblastoma protein, pRB. E2F4 is the major pRB-associated E2F in vivo, yet its role in Rb[superscript −/−] embryos is unknown. Here we establish that E2f4 deficiency reduced the lifespan of Rb[superscript −/−] embryos by exacerbating the Rb mutant placental defect. We further show that this reflects the accumulation of trophectoderm-like cells in both Rb and Rb;E2f4 mutant placentas. Thus, Rb and E2f4 play cooperative roles in placental development. We used a conditional mouse model to allow Rb[superscript −/−];E2f4[superscript −/−] embryos to develop in the presence of Rb wild-type placentas. Under these conditions, Rb[superscript −/−];E2f4[superscript −/−] mutants survived to birth. These Rb[superscript −/−];E2f4[superscript −/−] embryos exhibited all of the defects characteristic of the Rb and E2f4 single mutants and had no novel defects. Taken together, our data show that pRB and E2F4 cooperate in placental development, but play largely non-overlapping roles in the development of many embryonic tissues., David H. Koch Institute for Integrative Cancer Research at MIT. Pearl Staller Graduate Student Fund, National Institutes of Health (U.S.) (Grant GM53204), National Institutes of Health (U.S.) (Grant CA121921)

Published
2012

27. Mutation of p107 exacerbates the consequences of Rb loss in embryonic tissues and causes cardiac and blood vessel defects

Author

Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Lees , Jacqueline, Lees, Jacqueline, Caron, Alicia M., Danielian, Paul S., West, Julie C., Stone, James R., Berman, Seth D., Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Lees , Jacqueline, Lees, Jacqueline, Caron, Alicia M., Danielian, Paul S., West, Julie C., Stone, James R., and Berman, Seth D.

Abstract

The retinoblastoma tumor-suppressor protein, pRb, is a member of the pocket protein family that includes p107 and p130. These proteins have well-defined roles in regulating entry into and exit from the cell cycle and also have cell cycle–independent roles in facilitating differentiation. Here we investigate the overlap between pocket protein's function during embryonic development by using conditional mutant alleles to generate Rb;p107 double-mutant embryos (DKOs) that develop in the absence of placental defects. These DKOs die between e13.5 and e14.5, much earlier than either the conditional Rb or the germline p107 single mutants, which survive to birth or are largely viable, respectively. Analyses of the e13.5 DKOs shows that p107 mutation exacerbates the phenotypes resulting from pRb loss in the central nervous system and lens, but not in the peripheral nervous system. In addition, these embryos exhibit novel phenotypes, including increased proliferation of blood vessel endothelial cells, and heart defects, including double-outlet right ventricle (DORV). The DORV is caused, at least in part, by a defect in blood vessel endothelial cells and/or heart mesenchymal cells. These findings demonstrate novel, overlapping functions for pRb and p107 in numerous murine tissues.

Published
2010

37. Cystic malformation of the posterior cerebellar vermis in transgenic mice that ectopically express Engrailed-1, a homeodomain transcription factor

Author

Rowitch, David H., Danielian, Paul S., McMahon, Andrew P., and Zec, Natasa

Abstract

In WEXPZ-En-1 transgenic mice, Engrailed-1, a homeodomain-containing transcription factor, is ectopically expressed in the developing brain under control of the Wnt-1 enhancer. En-1 is a developmental regulatory control gene which has an essential role in the formation of the midbrain and cerebellum. Approximately 28% of WEXPZ-En-1+ mice develop cystic malformations of the posterior lobe of the cerebellar vermis, fourth ventricular dilatation, and postnatal hydrocephalus. These anatomic features are also found among the spectrum of posterior fossa malformations in humans. Expression characteristics of the WEXP transgene suggest that the neuropathology observed in WEXPZ-En-1+ mice stems from overexpression of En-1 during fetal and neonatal phases of cerebellar development. These observations raise the possibility that abnormal regulation of Engrailed genes, or targets of Engrailed, may be involved in the pathogenesis of cystic central nervous system malformations of the posterior fossa in humans. Teratology 60:22–28, 1999. © 1999 Wiley-Liss, Inc.

Published
1999
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38. Identification of an evolutionarily conserved 110 base-pair cis-acting regulatory sequence that governs Wnt-1 expression in the murine neural plate

Author

Rowitch, David H., Echelard, Yann, Danielian, Paul S., Gellner, Klaus, Brenner, Sydney, and McMahon, Andrew P.

Abstract

The generation of anterior-posterior polarity in the vertebrate brain requires the establishment of regional domains of gene expression at early somite stages. Wnt-1 encodes a signal that is expressed in the developing midbrain and is essential for midbrain and anterior hindbrain development. Previous work identified a 5.5 kilobase region located downstream of the Wnt-1 coding sequence which is necessary and sufficient for Wnt-1 expression in vivo. Using a transgenic mouse reporter assay, we have now identified a 110 base pair regulatory sequence within the 5.5 kilobase enhancer, which is sufficient for expression of a lacZ reporter in the approximate Wnt-1 pattern at neural plate stages. Multimers of this element driving Wnt-1 expression can partially rescue the midbrain-hindbrain phenotype of Wnt-1−/− embryos. The possibility that this region represents an evolutionarily conserved regulatory module is suggested by the identification of a highly homologous region located downstream of the wnt-1 gene in the pufferfish (Fugu rubripes). These sequences are capable of appropriate temporal and spatial activation of a reporter gene in the embryonic mouse midbrain; although, later aspects of the Wnt-1 expression pattern are absent. Genetic evidence has implicated Pax transcription factors in the regulation of Wnt-1. Although Pax-2 binds to the 110 base pair murine regulatory element in vitro, the location of the binding sites could not be precisely established and mutation of two putative low affinity sites did not abolish activation of a Wnt-1 reporter transgene in vivo. Thus, it is unlikely that Pax proteins regulate Wnt-1 by direct interactions with this cis-acting regulatory region. Our analysis of the 110 base pair minimal regulatory element suggests that Wnt-1 regulation is complex, involving different regulatory interactions for activation and the later maintenance of transgene expression in the dorsal midbrain and ventral diencephalon, and at the midbrain-hindbrain junction.

Published
1998
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39. Evidence that FGF8 signalling from the midbrain-hindbrain junction regulates growth and polarity in the developing midbrain

Author

Lee, Scott M. K., Danielian, Paul S., Fritzsch, Bernd, and McMahon, Andrew P.

Abstract

The developing vertebrate mesencephalon shows a rostrocaudal gradient in the expression of a number of molecular markers and in the cytoarchitectonic differentiation of the tectum, where cells cease proliferating and differentiate in a rostral to caudal progression. Tissue grafting experiments have implicated cell signalling by the mesencephalicmetencephalic (mid-hindbrain) junction (or isthmus) in orchestrating these events. We have explored the role of Wnt-1 and FGF8 signalling in the regulation of mesencephalic polarity. Wnt-1 is expressed in the caudal mesencephalon and Fgf8 in the most rostral metencephalon. Wnt-1 regulates Fgf8 expression in the adjacent metencephalon, most likely via a secondary mesencephalic signal. Ectopic expression of Fgf8 in the mesencephalon is sufficient to activate expression of Engrailed-2 (En-2) and ELF-1, two genes normally expressed in a decreasing caudal to rostral gradient in the posterior mesencephalon. Ectopic expression of Engrailed-1 (En-1), a functionally equivalent homologue of En-2 is sufficient to activate ELF-1 expression by itself. These results indicate the existence of a molecular hierarchy in which FGF8 signalling establishes the graded expression of En-2 within the tectum. This in turn may act to specify other aspects of A-P polarity such as graded ELF-1 expression. Our studies also reveal that FGF8 is a potent mitogen within the mesencephalon: when ectopically expressed, neural precursors continue to proliferate and neurogenesis is prevented. Taken together our results suggest that FGF8 signalling from the isthmus has a key role in coordinately regulating growth and polarity in the developing mesencephalon.

Published
1997
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43. E2F4 cooperates with pRB in the development of extra-embryonic tissues

Author

Jacqueline A. Lees, Tina L. Yuan, Paul S. Danielian, Julie C. West, Eunice Y. Lee, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Lee, Eunice Y., Yuan, Tina L., Danielian, Paul S., West, Julie C., and Lees, Jacqueline

Subjects
Erythrocytes, Placenta, Proliferation, Mutant, Extraembryonic Membranes, Embryonic Development, Apoptosis, E2F4 Transcription Factor, Biology, Retinoblastoma Protein, Article, Mice, pRB, medicine, Animals, E2F, Molecular Biology, E2F4, Cell Proliferation, Oligonucleotide Array Sequence Analysis, Mice, Knockout, Retinoblastoma, Gene Expression Profiling, Embryogenesis, Retinoblastoma protein, Gene Expression Regulation, Developmental, Anemia, Embryo, Cell Biology, Embryo, Mammalian, medicine.disease, Survival Analysis, Embryonic stem cell, Dppa5, Cell biology, Phenotype, Mutation, embryonic structures, Embryo Loss, Cancer research, biology.protein, Trophectoderm, Female, Biomarkers, Developmental Biology
Abstract

August 1, 2010, The retinoblastoma gene, RB-1, was the first identified tumor suppressor. Rb[superscript −/−] mice die in mid-gestation with defects in proliferation, differentiation and apoptosis. The activating E2F transcription factors, E2F1–3, contribute to these embryonic defects, indicating that they are key downstream targets of the retinoblastoma protein, pRB. E2F4 is the major pRB-associated E2F in vivo, yet its role in Rb[superscript −/−] embryos is unknown. Here we establish that E2f4 deficiency reduced the lifespan of Rb[superscript −/−] embryos by exacerbating the Rb mutant placental defect. We further show that this reflects the accumulation of trophectoderm-like cells in both Rb and Rb;E2f4 mutant placentas. Thus, Rb and E2f4 play cooperative roles in placental development. We used a conditional mouse model to allow Rb[superscript −/−];E2f4[superscript −/−] embryos to develop in the presence of Rb wild-type placentas. Under these conditions, Rb[superscript −/−];E2f4[superscript −/−] mutants survived to birth. These Rb[superscript −/−];E2f4[superscript −/−] embryos exhibited all of the defects characteristic of the Rb and E2f4 single mutants and had no novel defects. Taken together, our data show that pRB and E2F4 cooperate in placental development, but play largely non-overlapping roles in the development of many embryonic tissues., David H. Koch Institute for Integrative Cancer Research at MIT. Pearl Staller Graduate Student Fund, National Institutes of Health (U.S.) (Grant GM53204), National Institutes of Health (U.S.) (Grant CA121921)

Published
2009
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44. E2f4 and E2f5 are essential for the development of the male reproductive system

Author

Jacqueline A. Lees, Paul S. Danielian, Rex A. Hess, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S, and Lees, Jacqueline

Subjects
0301 basic medicine, Male, medicine.medical_specialty, E2F4 Transcription Factor, Biology, 03 medical and health sciences, Mice, 0302 clinical medicine, Rete testis, Internal medicine, Report, medicine, Animals, Spermatogenesis, Molecular Biology, E2F4, Crosses, Genetic, Mice, Knockout, E2F5 Transcription Factor, Rete Testis, Aquaporin 1, Integrases, Efferent ducts, Gene Expression Regulation, Developmental, Cell Biology, Cell cycle, Seminiferous Tubules, Sperm, Spermatozoa, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Endocrinology, Clusterin, 030220 oncology & carcinogenesis, Female, Homeostasis, Developmental Biology, Signal Transduction
Abstract

The E2F transcription factors are primarily implicated in the regulation of entry and exit from the cell cycle. However, in vivo studies have established additional roles for E2Fs during organ development and homeostasis. With the goal of addressing the intestinal requirements of E2f4 and E2f5, we crossed mice carrying Vil-cre, E2f4 conditional and E2f5 germline alleles. E2f4 deletion had no detectable effect on intestinal development. However, E2f4f/f;E2f5+/−;Vil-cre males, but not E2f4f/f;Vil-cre littermates, were unexpectedly sterile. This defect was not due to defective spermatogenesis. Instead, the seminiferous tubules and rete testes showed significant dilation, and spermatozoa accumulated aberrantly in the rete testis and efferent ducts. Our data show that these problems result from defective efferent ducts, a tissue whose primary function is to concentrate sperm through fluid absorption. First, Vil-cre expression, and consequent E2F4 loss, was specific to the efferent ducts and not other reproductive tract tissues. Second, the E2f4f/f;E2f5+/−;Vil-cre efferent ducts had completely lost multiciliated cells and greatly reduced levels of critical absorptive cell proteins: aquaporin1, a water channel protein, and clusterin, an endocytic marker. Collectively, the observed testis phenotypes suggest a fluid flux defect. Remarkably, we observed rete testis dilation prior to the normal time of seminiferous fluid production, arguing that the efferent duct defects promote excessive secretory activity within the reproductive tract. Finally, we also detect key aspects of these testis defects in E2f5−/− mice. Thus, we conclude that E2f4 and E2f5 display overlapping roles in controlling the normal development of the male reproductive system., National Institutes of Health (U.S.) (Grant NIH-P01 CA42063)

Published
2015

45. Proteomic analysis of pRb loss highlights a signature of decreased mitochondrial oxidative phosphorylation

Author

Paul S. Danielian, Mantre Dehnad, Jacqueline A. Lees, Brandon Nicolay, Wilhelm Haas, Ioannis Sanidas, Nicholas J. Dyson, Filippos Kottakis, Kevin M. Haigis, John D. Lapek, Robert Morris, Katrin Tschöp, Amity L. Manning, Nabeel Bardeesy, Jessica J. Gierut, Wayne O. Miles, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S., and Lees, Jacqueline

Subjects
Proteomics, Colon, Oxidative phosphorylation, Mitochondrion, Retinoblastoma Protein, Oxidative Phosphorylation, Mitochondrial Proteins, Gene Knockout Techniques, Mice, Stress, Physiological, Gene expression, Genetics, Animals, Humans, E2F, skin and connective tissue diseases, Lung, Cells, Cultured, Regulation of gene expression, biology, Retinoblastoma protein, Molecular biology, Chromatin, Mitochondria, Citric acid cycle, Gene Expression Regulation, biology.protein, sense organs, Transcriptome, Resource/Methodology, Developmental Biology
Abstract

The retinoblastoma tumor suppressor (pRb) protein associates with chromatin and regulates gene expression. Numerous studies have identified Rb-dependent RNA signatures, but the proteomic effects of Rb loss are largely unexplored. We acutely ablated Rb in adult mice and conducted a quantitative analysis of RNA and proteomic changes in the colon and lungs, where Rb[superscript KO] was sufficient or insufficient to induce ectopic proliferation, respectively. As expected, Rb[superscript KO] caused similar increases in classic pRb/E2F-regulated transcripts in both tissues, but, unexpectedly, their protein products increased only in the colon, consistent with its increased proliferative index. Thus, these protein changes induced by Rb loss are coupled with proliferation but uncoupled from transcription. The proteomic changes in common between Rb[superscript KO] tissues showed a striking decrease in proteins with mitochondrial functions. Accordingly, RB1 inactivation in human cells decreased both mitochondrial mass and oxidative phosphorylation (OXPHOS) function. Rb[superscript KO] cells showed decreased mitochondrial respiratory capacity and the accumulation of hypopolarized mitochondria. Additionally, RB/Rb loss altered mitochondrial pyruvate oxidation from [superscript 13]C-glucose through the TCA cycle in mouse tissues and cultured cells. Consequently, Rb[superscript KO] cells have an enhanced sensitivity to mitochondrial stress conditions. In summary, proteomic analyses provide a new perspective on Rb/RB1 mutation, highlighting the importance of pRb for mitochondrial function and suggesting vulnerabilities for treatment., National Institutes of Health (U.S.) (2-P01-CA42063)

Published
2015

46. Loss of pRB and p107 disrupts cartilage development and promotes enchondroma formation

Author

Jacqueline A. Lees, Paul S. Danielian, Allison S. Landman, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Danielian, Paul S., Lees, Jacqueline, and Landman, A. S.

Subjects
Cancer Research, Mesenchyme, Retinoblastoma-Like Protein p107, Real-Time Polymerase Chain Reaction, Retinoblastoma Protein, Chondrocyte, Article, Mice, Genetics, medicine, Enchondroma, Animals, Growth Plate, E2F, Molecular Biology, Endochondral ossification, Mice, Knockout, biology, Cartilage, Retinoblastoma protein, Anatomy, Chondrogenesis, medicine.disease, Cell biology, medicine.anatomical_structure, embryonic structures, Mutation, biology.protein, biological phenomena, cell phenomena, and immunity, Tomography, X-Ray Computed, Chondroma
Abstract

The pocket proteins pRB, p107 and p130 have established roles in regulating the cell cycle through the control of E2F activity. The pocket proteins regulate differentiation of a number of tissues in both cell cycle-dependent and -independent manners. Prior studies showed that mutation of p107 and p130 in the mouse leads to defects in cartilage development during endochondral ossification, the process by which long bones form. Despite evidence of a role for pRB in osteoblast differentiation, it is unknown whether it functions during cartilage development. Here, we show that mutation of Rb in the early mesenchyme of p107-mutant mice results in severe cartilage defects in the growth plates of long bones. This is attributable to inappropriate chondrocyte proliferation that persists after birth and leads to the formation of enchondromas in the growth plates as early as 8 weeks of age. Genetic crosses show that development of these tumorigenic lesions is E2f3 dependent. These results reveal an overlapping role for pRB and p107 in cartilage development, endochondral ossification and enchondroma formation that reflects their coordination of cell-cycle exit at appropriate developmental stages., Virginia and D.K. Ludwig Fund for Cancer Research (Fellowship), National Cancer Institute (U.S.) (Grant CA121921)

Published
2012

47. Rb regulates fate choice and lineage commitment in vivo

Author

Simona Nedelcu, Paul S. Danielian, Jacqueline A. Lees, Jose A. Quintero-Estades, Seth D. Berman, Eliezer Calo, Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Calo, Eliezer, Quintero-Estades, Jose A., Danielian, Paul S., Nedelcu, Simona, Berman, Seth D., and Lees, Jacqueline

Subjects
Tumor suppressor gene, Cellular differentiation, Adipose Tissue, White, Core Binding Factor Alpha 1 Subunit, Retinoblastoma Protein, Article, Mice, Adipose Tissue, Brown, Cell Line, Tumor, medicine, Animals, Cell Lineage, E2F, Genetics, Multidisciplinary, Osteoblasts, biology, Retinoblastoma, Gene Expression Profiling, Retinoblastoma protein, Cell Differentiation, Sarcoma, medicine.disease, Cell biology, RUNX2, PPAR gamma, Disease Models, Animal, Gene Expression Regulation, Adipogenesis, Mutation, biology.protein, Lipoma, E2F Transcription Factors
Abstract

February 1, 2011, Mutation of the retinoblastoma gene (RB1) tumour suppressor occurs in one-third of all human tumours and is particularly associated with retinoblastoma and osteosarcoma[superscript 1]. Numerous functions have been ascribed to the product of the human RB1 gene, the retinoblastoma protein (pRb). The best known is pRb’s ability to promote cell-cycle exit through inhibition of the E2F transcription factors and the transcriptional repression of genes encoding cell-cycle regulators[superscript 1]. In addition, pRb has been shown in vitro to regulate several transcription factors that are master differentiation inducers[superscript 2]. Depending on the differentiation factor and cellular context, pRb can either suppress or promote their transcriptional activity. For example, pRb binds to Runx2 and potentiates its ability to promote osteogenic differentiation in vitro[superscript 3]. In contrast, pRb acts with E2F to suppress peroxisome proliferator-activated receptor γ subunit (PPAR-γ), the master activator of adipogenesis[superscript 4, 5]. Because osteoblasts and adipocytes can both arise from mesenchymal stem cells, these observations suggest that pRb might play a role in the choice between these two fates. However, so far, there is no evidence for this in vivo. Here we use mouse models to address this hypothesis in mesenchymal tissue development and tumorigenesis. Our data show that Rb status plays a key role in establishing fate choice between bone and brown adipose tissue in vivo., National Cancer Institute (U.S.) (Grant), National Institutes of Health (U.S.) (Grant)

Published
2010

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