Michael Fetchko scite author profile

Binding of epidermal growth factor (EGF) to its receptor leads to receptor dimerization, assembly of protein complexes, and activation of signaling networks that control key cellular responses. Despite their fundamental role in cell biology, little is known about protein complexes associated with the EGF receptor (EGFR) before growth factor stimulation. We used a modified membrane yeast two-hybrid system together with bioinformatics to identify 87 candidate proteins interacting with the ligand-unoccupied EGFR. Among them was histone deacetylase 6 (HDAC6), a cytoplasmic lysine deacetylase, which we found negatively regulated EGFR endocytosis and degradation by controlling the acetylation status of alpha-tubulin and, subsequently, receptor trafficking along microtubules. A negative feedback loop consisting of EGFR-mediated phosphorylation of HDAC6 Tyr(570) resulted in reduced deacetylase activity and increased acetylation of alpha-tubulin. This study illustrates the complexity of the EGFR-associated interactome and identifies protein acetylation as a previously unknown regulator of receptor endocytosis and degradation.

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Application of the split-ubiquitin membrane yeast two-hybrid system to investigate membrane protein interactions

Fetchko

Štagljar

2004

Methods

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Drosophila clock cells use multiple mechanisms to transmit time-of-day signals in the brain

Barber

Fong

Kolesnik

et al. 2021

Proc. Natl. Acad. Sci. U.S.A.

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Regulation of circadian behavior and physiology by the Drosophila brain clock requires communication from central clock neurons to downstream output regions, but the mechanism by which clock cells regulate downstream targets is not known. We show here that the pars intercerebralis (PI), previously identified as a target of the morning cells in the clock network, also receives input from evening cells. We determined that morning and evening clock neurons have time-of-day–dependent connectivity to the PI, which is regulated by specific peptides as well as by fast neurotransmitters. Interestingly, PI cells that secrete the peptide DH44, and control rest:activity rhythms, are inhibited by clock inputs while insulin-producing cells (IPCs) are activated, indicating that the same clock cells can use different mechanisms to drive cycling in output neurons. Inputs of morning cells to IPCs are relevant for the circadian rhythm of feeding, reinforcing the role of the PI as a circadian relay that controls multiple behavioral outputs. Our findings provide mechanisms by which clock neurons signal to nonclock cells to drive rhythms of behavior.

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Scabrous and Gp150 are endosomal proteins that regulate Notch activity

Fetchko

Lai

et al. 2003

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Figure 5 of this paper illustrates the distribution of Sca protein and of several deletions of Sca after heatshock-induced expression in the pupal retina of Drosophila. Owing to confusion between two plasmids in N.E.B.'s laboratory, the preparation labelled Sca∆41-514 in Fig. 5G was, in fact, expressing a different protein, Sca∆319-463. When the experiment was repeated using the correct genotypes, we found that whereas full-length Sca associated with the lattice of pigment cells that express the Notch protein at high levels, Sca∆41-514 associated predominantly with other cells. The results indicate that the N-terminal 514 amino acids of Sca mediate colocalization with Notch, not the Fibrinogen-Related Domain contained within amino acids 515-774. We apologize to readers for this mistake, which does not affect the major conclusions of the paper. A revised version of Fig. 5 and its legend are shown below.

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Drosophila Gp150 is required for early ommatidial development through modulation of Notch signaling

Fetchko

Huang

Liu

et al. 2002

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Cellular signaling activities must be tightly regulated for proper cell fate control and tissue morphogenesis. Here we report that the Drosophila leucine‐rich repeat transmembrane glycoprotein Gp150 is required for viability, fertility and development of the eye, wing and sensory organs. In the eye, Gp150 plays a critical role in regulating early ommatidial formation. Gp150 is highly expressed in cells of the morphogenetic furrow (MF) region, where it accumulates exclusively in intracellular vesicles in an endocytosis‐independent manner. Loss of gp150 function causes defects in the refinement of photoreceptor R8 cells and recruitment of other cells, which leads to the formation of aberrant ommatidia. Genetic analyses suggest that Gp150 functions to modulate Notch signaling. Consistent with this notion, Gp150 is co‐localized with Delta in intracellular vesicles in cells within the MF region and loss of gp150 function causes accumulation of intracellular Delta protein. Therefore, Gp150 might function in intracellular vesicles to modulate Delta–Notch signaling for cell fate control and tissue morphogenesis.

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Michael Fetchko

Regulation of Epidermal Growth Factor Receptor Trafficking by Lysine Deacetylase HDAC6

Application of the split-ubiquitin membrane yeast two-hybrid system to investigate membrane protein interactions

Drosophila clock cells use multiple mechanisms to transmit time-of-day signals in the brain

Scabrous and Gp150 are endosomal proteins that regulate Notch activity

Drosophila Gp150 is required for early ommatidial development through modulation of Notch signaling

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