Your search keyword '"Ngoc Han Tran"' showing total 2 results

1. Quantitative microscopy reveals dynamics and fate of clustered IRE1α

Author

Vladislav Belyy, Ngoc-Han Tran, and Peter Walter

Subjects

IRE1, Protein Serine-Threonine Kinases, Endoplasmic Reticulum, Vaccine Related, Mice, 03 medical and health sciences, Cytosol, Ribonucleases, 0302 clinical medicine, Biodefense, Endoribonucleases, Cluster (physics), Animals, Humans, Cluster Analysis, Ribonuclease, Cluster analysis, 030304 developmental biology, Microscopy, 0303 health sciences, Multidisciplinary, biology, Chemistry, Prevention, Endoplasmic reticulum, quantitative microscopy, unfolded protein response, Protein-Serine-Threonine Kinases, Endoplasmic Reticulum Stress, 3. Good health, Emerging Infectious Diseases, Cytoplasm, Quantitative Microscopy, Unfolded protein response, biology.protein, Cluster size, Biophysics, Generic health relevance, signaling, 030217 neurology & neurosurgery, Signal Transduction, clustering

Abstract

The endoplasmic reticulum (ER) membrane-resident stress sensor inositol-requiring enzyme 1 (IRE1) governs the most evolutionarily conserved branch of the unfolded protein response. Upon sensing an accumulation of unfolded proteins in the ER lumen, IRE1 activates its cytoplasmic kinase and ribonuclease domains to transduce the signal. IRE1 activity correlates with its assembly into large clusters, yet the biophysical characteristics of IRE1 clusters remain poorly characterized. We combined superresolution microscopy, single-particle tracking, fluorescence recovery, and photoconversion to examine IRE1 clustering quantitatively in living human and mouse cells. Our results revealed that: 1) In contrast to qualitative impressions gleaned from microscopic images, IRE1 clusters comprise only a small fraction (∼5%) of the total IRE1 in the cell; 2) IRE1 clusters have complex topologies that display features of higher-order organization; 3) IRE1 clusters contain a diffusionally constrained core, indicating that they are not phase-separated liquid condensates; 4) IRE1 molecules in clusters remain diffusionally accessible to the free pool of IRE1 molecules in the general ER network; 5) when IRE1 clusters disappear at later time points of ER stress as IRE1 signaling attenuates, their constituent molecules are released back into the ER network and not degraded; 6) IRE1 cluster assembly and disassembly are mechanistically distinct; and 7) IRE1 clusters' mobility is nearly independent of cluster size. Taken together, these insights define the clusters as dynamic assemblies with unique properties. The analysis tools developed for this study will be widely applicable to investigations of clustering behaviors in other signaling proteins.

Published

2019

2. Defining the impact of mutation accumulation on replicative lifespan in yeast using cancer-associated mutator phenotypes

Author

Scott R. Kennedy, Alan J. Herr, Thu H. B. Tran, Ian T. Dowsett, Mitchell B. Lee, Niloufar Ghodsian, Anh B. Diep, Michael G. Kiflezghi, Michael S. Chung, Daniel T. Carr, Katherine A. Grayden, Anna Bode, Thao T Tang, Priya A. Uppal, Daniel E. L. Promislow, Ngoc Han Tran, Brian M. Wasko, Sarah G. Stanton, Yordanos C. Elala, Michael Hope, and Matt Kaeberlein

Subjects

DNA Replication, Aging, Mutation rate, Saccharomyces cerevisiae Proteins, Lineage (genetic), DNA Repair, Genotype, Somatic cell, Longevity, Saccharomyces cerevisiae, Biology, DNA Mismatch Repair, Mutation Accumulation, Mutation Rate, Neoplasms, Humans, Genetics, Multidisciplinary, Whole Genome Sequencing, Phenotype, PNAS Plus, Mutation, Mutation (genetic algorithm), DNA mismatch repair, Ploidy

Abstract

Mutations accumulate within somatic cells and have been proposed to contribute to aging. It is unclear what level of mutation burden may be required to consistently reduce cellular lifespan. Human cancers driven by a mutator phenotype represent an intriguing model to test this hypothesis, since they carry the highest mutation burdens of any human cell. However, it remains technically challenging to measure the replicative lifespan of individual mammalian cells. Here, we modeled the consequences of cancer-related mutator phenotypes on lifespan using yeast defective for mismatch repair (MMR) and/or leading strand (Polε) or lagging strand (Polδ) DNA polymerase proofreading. Only haploid mutator cells with significant lifetime mutation accumulation (MA) exhibited shorter lifespans. Diploid strains, derived by mating haploids of various genotypes, carried variable numbers of fixed mutations and a range of mutator phenotypes. Some diploid strains with fewer than two mutations per megabase displayed a 25% decrease in lifespan, suggesting that moderate numbers of random heterozygous mutations can increase mortality rate. As mutation rates and burdens climbed, lifespan steadily eroded. Strong diploid mutator phenotypes produced a form of genetic anticipation with regard to aging, where the longer a lineage persisted, the shorter lived cells became. Using MA lines, we established a relationship between mutation burden and lifespan, as well as population doubling time. Our observations define a threshold of random mutation burden that consistently decreases cellular longevity in diploid yeast cells. Many human cancers carry comparable mutation burdens, suggesting that while cancers appear immortal, individual cancer cells may suffer diminished lifespan due to accrued mutation burden.

Published

2019