Susan J. Hayes

TGFβ receptor internalization into EEA1-enriched early endosomes: role in signaling to Smad2

Transforming growth factor (TGF)β is an important physiological regulator of cellular growth and differentiation. It activates a receptor threonine/serine kinase that phosphorylates the transcription factor Smad2, which then translocates into the nucleus to trigger specific transcriptional events. Here we show that activated type I and II TGFβ receptors internalize into endosomes containing the early endosomal protein EEA1. The extent of TGFβ-stimulated Smad2 phosphorylation, Smad2 nuclear translocation, and TGFβ-stimulated transcription correlated closely with the extent of internalization of the receptor. TGFβ signaling also requires SARA (Smad anchor for receptor activation), a 135-kD polypeptide that contains a FYVE Zn++ finger motif. Here we show that SARA localizes to endosomes containing EEA1, and that disruption of this localization inhibits TGFβ-induced Smad2 nuclear translocation. These results indicate that traffic of the TGFβ receptor into the endosome enables TGFβ signaling, revealing a novel function for the endosome as a compartment specialized for the amplification of certain extracellular signals.

Stimulation of neural regeneration in the mouse retina.

Müller glia can serve as a source of new neurons after retinal damage in both fish and birds. Investigations of regeneration in the mammalian retina in vitro have provided some evidence that Müller glia can proliferate after retinal damage and generate new rods; however, the evidence that this occurs in vivo is not conclusive. We have investigated whether Müller glia have the potential to generate neurons in the mouse retina in vivo by eliminating ganglion and amacrine cells with intraocular NMDA injections and stimulating Müller glial to re-enter the mitotic cycle by treatment with specific growth factors. The proliferating Müller glia dedifferentiate and a subset of these cells differentiated into amacrine cells, as defined by the expression of amacrine cell-specific markers Calretinin, NeuN, Prox1, and GAD67-GFP. These results show for the first time that the mammalian retina has the potential to regenerate inner retinal neurons in vivo.

Multivalent Endosome Targeting by Homodimeric EEA1

Early endosome autoantigen localization to early endosomes is mediated by a C-terminal region, which includes a calmodulin binding motif, a Rab5 interaction site, and a FYVE domain that selectively binds phosphatidyl inositol 3-phosphate. The crystal structure of the C-terminal region bound to inositol 1,3-bisphosphate reveals an organized, quaternary assembly consisting of a parallel coiled coil and a dyad-symmetric FYVE domain homodimer. Structural and biochemical observations support a multivalent mechanism for endosomal localization in which domain organization, dimerization, and quaternary structure amplify the weak affinity and modest specificity of head group interactions with conserved residues. A unique mode of membrane engagement deduced from the quaternary structure of the C-terminal region provides insight into the structural basis of endosome tethering.

Structural Basis for Endosomal Targeting by FYVE Domains

The FYVE domain is a conserved protein motif characterized by its ability to bind with high affinity and specificity to phosphatidylinositol 3-phosphate (PI(3)P), a phosphoinositide highly enriched in early endosomes. The PI(3)P polar head group contacts specific amino acid residues that are conserved among FYVE domains. Despite full conservation of these residues, the ability of different FYVE domains to bind to endosomes in cells is highly variable. Here we show that the endosomal localization in intact cells absolutely requires structural features intrinsic to the FYVE domain in addition to the PI(3)P binding pocket. These features are involved in FYVE domain dimerization and in interaction with the membrane bilayer. These interactions, which are determined by non-conserved residues, are likely to be essential for the temporal and spatial control of protein associations at the membrane-cytosol interface within the endocytic pathway.

NeuroD1 Regulates Expression of Thyroid Hormone Receptor β2 and Cone Opsins in the Developing Mouse Retina

The correct patterning of opsin expression in cone photoreceptors is critical for normal color vision. Thyroid hormone, and one of its receptors [thyroid hormone receptor β2 (TRβ2)], is an important regulator of opsin expression during cone photoreceptor development. Mice have two genes, encoding medium-wavelength (M) and short-wavelength (S) cone opsins. Targeted deletion of TRβ2 leads to a uniform expression of S-opsin in all cone photoreceptors and a loss of M-opsin. The control of expression of TRβ2 is therefore central to cone differentiation, yet there is little known about its regulation in the retina. We now report that the proneural bHLH (basic helix-loop-helix) transcription factor, NeuroD1, is necessary for sustained expression of TRβ2 in immature cone photoreceptors. Mice deficient in NeuroD1 develop an opsin phenotype virtually identical with that of TRβ2-deficient mice: all cones express S-opsin, and none expresses M-opsin. The introduction of NeuroD1 into embryonic retinal explants from NeuroD1−/− mice restores TRβ2 expression. NeuroD1 binds an E-box in the intron control region of the TRβ2 gene that mediates cone-specific expression, suggesting that NeuroD1 is a critical contributory factor to the expression of TRβ2 in cones. These results thus connect the proneural pathway with opsin selection to ensure correct cone patterning during retinal development.

The WD40 and FYVE domain containing protein 2 defines a class of early endosomes necessary for endocytosis

The FYVE domain binds with high specificity and avidity to phosphatidylinositol 3-phosphate. It is present in ≈30 proteins in humans, some of which have been implicated in functions ranging from early endosome fusion to signal transduction through the TGF-β receptor. To develop a further understanding of the biological roles of this protein family, we turned to the nematode Caenorhabditis elegans, which contains only 12 genes predicted to encode for phosphatidylinositol 3-phosphate binding, FYVE domain-containing proteins, all of which have homologs in the human genome. Each of these proteins was targeted individually by RNA interference. One protein, WDFY2, produced a strong inhibition of endocytosis when silenced. WDFY2 contains WD40 motifs and a FYVE domain, is highly conserved between species, and localizes to a set of small endosomes that reside within 100 nm from the plasma membrane. These endosomes are involved in transferrin uptake but lack the classical endosomal markers Rab5 and EEA1. Silencing of WDFY2 by siRNA in mammalian cells impaired transferrin endocytosis. These studies reveal the important, conserved role of WDFY2 in endocytosis, and the existence of a subset of early endosomes, closely associated with the plasma membrane, that may constitute the first stage of endocytic processing of internalized cargo.

BAF60c is a component of the neural progenitor specific BAF complex in developing retina

Remodeling of the chromatin network plays an important role regulating embryonic development as well as differentiation. The SWI/SNF complex is an ATP‐dependent chromatin‐remodeling complex. It consists of several proteins, including an ATPase subunit, either Brg1 or Brm. Two subunits of this complex, Baf53a and Baf45, have been previously identified as being neural progenitor‐specific. In this study, we show that Baf60c, another important part of this large complex, acts in a similar neural progenitor–specific manner. We show that during development Baf60c is expressed in neural progenitors in human retinas as well as mouse retina, cortex and spinal cord. Baf60c expression is lost during neural differentiation and its overexpression keeps the progenitors in a proliferative state through its interaction with the Notch pathway. Finally, we show that Baf60c is re‐expressed in the Müller glial cells that re‐enter the cell cycle after neurotoxic damage. Developmental Dynamics 237:3016–3023, 2008.