Erik F. Y. Hom scite author profile

The endoplasmic reticulum (ER) is the major compartment for the processing and quality control of newly synthesized proteins. Green fluorescent protein (GFP) was used as a noninvasive probe to determine the viscous properties of the aqueous lumen of the ER. GFP was targeted to the ER lumen of CHO cells by transient transfection with cDNA encoding GFP (S65T/F64L mutant) with a C-terminus KDEL retention sequence and upstream prolactin secretory sequence. Repeated laser illumination of a fixed 2-micrometers diameter spot resulted in complete bleaching of ER-associated GFP throughout the cell, indicating a continuous ER lumen. A residual amount (<1%) of GFP-KDEL was perinuclear and noncontiguous with the ER, presumably within a pre- or cis-Golgi compartment involved in KDEL-substrate retention. Quantitative spot photobleaching with a single brief bleach pulse indicated that GFP was fully mobile with a t1/2 for fluorescence recovery of 88 +/- 5 ms (SE; 60x lens) and 143 +/- 8 ms (40x). Fluorescence recovery was abolished by paraformaldehyde except for a small component of reversible photobleaching with t1/2 of 3 ms. For comparison, the t1/2 for photobleaching of GFP in cytoplasm was 14 +/- 2 ms (60x) and 24 +/- 1 ms (40x). Utilizing a mathematical model that accounted for ER reticular geometry, a GFP diffusion coefficient of 0.5-1 x 10(-7) cm2/s was computed, 9-18-fold less than that in water and 3-6-fold less than that in cytoplasm. By frequency-domain microfluorimetry, the GFP rotational correlation time was measured to be 39 +/- 8 ns, approximately 2-fold greater than that in water but comparable to that in the cytoplasm. Fluorescence recovery after photobleaching using a 40x lens was measured (at 23 degrees C unless otherwise indicated) for several potential effectors of ER structure and/or lumen environment: t1/2 values (in ms) were 143 +/- 8 (control), 100 +/- 13 (37 degrees C), 53 +/- 13 (brefeldin A), and 139 +/- 6 (dithiothreitol). These results indicate moderately slowed GFP diffusion in a continuous ER lumen.

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Metabolic network reconstruction of Chlamydomonas offers insight into light‐driven algal metabolism

Chang

Ghamsari

Manichaikul

et al. 2011

Molecular Systems Biology

280

270

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Fungi in the Marine Environment: Open Questions and Unsolved Problems

Amend

Burgaud

Cunliffe

et al. 2019

mBio

240

201

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Terrestrial fungi play critical roles in nutrient cycling and food webs and can shape macroorganism communities as parasites and mutualists. Although estimates for the number of fungal species on the planet range from 1.5 to over 5 million, likely fewer than 10% of fungi have been identified so far. To date, a relatively small percentage of described species are associated with marine environments, with ∼1,100 species retrieved exclusively from the marine environment. Nevertheless, fungi have been found in nearly every marine habitat explored, from the surface of the ocean to kilometers below ocean sediments. Fungi are hypothesized to contribute to phytoplankton population cycles and the biological carbon pump and are active in the chemistry of marine sediments. Many fungi have been identified as commensals or pathogens of marine animals (e.g., corals and sponges), plants, and algae. Despite their varied roles, remarkably little is known about the diversity of this major branch of eukaryotic life in marine ecosystems or their ecological functions. This perspective emerges from a Marine Fungi Workshop held in May 2018 at the Marine Biological Laboratory in Woods Hole, MA. We present the state of knowledge as well as the multitude of open questions regarding the diversity and function of fungi in the marine biosphere and geochemical cycles.

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Niche engineering demonstrates a latent capacity for fungal-algal mutualism

Hom

Murray

2014

Science

201

178

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Mutualistic symbioses shape the evolution of species and ecosystems and catalyze the emergence of biological complexity, yet how such symbioses first form is unclear. We show that an obligate mutualism between the yeast Saccharomyces cerevisiae and the alga Chlamydomonas reinhardtii—two model eukaryotes with very different life histories—can arise spontaneously in an environment requiring reciprocal carbon and nitrogen exchange. This capacity for mutualism is phylogenetically broad, extending to other Chlamydomonas and fungal species. Furthermore, we witnessed the spontaneous association of Chlamydomonas algal cells physically interacting with filamentous fungi. These observations demonstrate that under specific conditions, environmental change induces free-living species to become obligate mutualists and establishes a set of experimentally tractable, phylogenetically related, synthetic systems for studying the evolution of symbiosis.

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Erik F. Y. Hom

Diffusion of Green Fluorescent Protein in the Aqueous-Phase Lumen of Endoplasmic Reticulum

Metabolic network reconstruction of Chlamydomonas offers insight into light‐driven algal metabolism

Fungi in the Marine Environment: Open Questions and Unsolved Problems

Niche engineering demonstrates a latent capacity for fungal-algal mutualism

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