Cell Powerhouses Break Down Cleaning Up Misfolded Proteins
Credit: Erli Jin and Linhao Ruan, Johns Hopkins Medicine
Working with yeast and human cells, researchers at Johns Hopkins say they have discovered an unexpected route for cells to eliminate protein clumps that may sometimes be the molecular equivalent of throwing too much or the wrong trash into the garbage disposal. Their finding, they say, could help explain part of what goes awry in the progression of such neurodegenerative diseases as Parkinson’s and Alzheimer’s.
Proteins in the cell that are damaged or folded incorrectly tend to form clumps or aggregates, which have been thought to dissolve gradually in a cell’s cytoplasm or nucleus thanks to an enzyme complex called the proteasome, or in a digestive organelle called the lysosome.
In experiments on yeast, which has many structures similar to those in human cells, the Johns Hopkins scientists unexpectedly found that many of those protein clumps break down in the cell’s energy-producing powerhouses, called mitochondria. They also found that too many misfolded proteins can clog up and damage this vital structure. The team’s findings, described March 1 in Nature, could help explain why protein clumping and mitochondrial deterioration are both hallmarks of neurodegenerative diseases.
Rong Li, Ph.D., professor of cell biology, chemical and biomolecular engineering, and oncology at the Johns Hopkins University and a member of the Johns Hopkins Kimmel Cancer Center, who led the study, likens the disposal system to the interplay between a household’s trash and a garbage disposal in the kitchen sink. The disposal is handy and helps keep the house free of food scraps, but the danger is that with too much trash, especially tough-to-grind garbage, the system could get clogged up or break down.
In a previous study, Li and her team found protein aggregates, which form abundantly under stressful conditions, such as intense heat, stuck to the outer surface of mitochondria. In this study, they found the aggregates bind to proteins that form the pores mitochondria normally use to import proteins needed to build this organelle. If these pores are damaged by mutations, then aggregates cannot be dissolved, the researchers report. These observations led the team to hypothesize that misfolded proteins in the aggregates are pulled into mitochondria for disposal, much like food scraps dropped into the garbage disposal. Testing this hypothesis was tricky, Li says, because most of the misfolded proteins started out in the cytoplasm, and most of those that enter mitochondria quickly get ground up.
As a consequence, Li and her team used a technique in which a fluorescent protein was split into two parts. Then, they put one part inside the mitochondria and linked the other part with a misfolded and clumping protein in the cytoplasm. If the misfolded protein entered the mitochondria, the two parts of the fluorescent protein could come together and light up the mitochondria. This was indeed what happened.
“With any experiment,” Li says, “you have a hypothesis, but in your head, you may be skeptical, so seeing the bright mitochondria was an enlightening moment.”
To see what might happen in a diseased system, the team then put into yeast cells a protein implicated in the neurodegenerative disease known as amyotrophic lateral sclerosis (ALS), or Lou Gehrig’s disease. After a heat treatment that caused the ALS protein to misfold, it also wound up in the mitochondria. The researchers then did an experiment in which a lot of proteins in the cytoplasm were made to misfold and found that when too much of these proteins entered mitochondria, they started to break down.
The team wanted to make sure that the phenomenon it had observed in the yeast cells could also happen in human cells, so the scientists used the same split-fluorescent protein method to observe misfolded proteins to enter the mitochondria of lab-grown human retinal pigmented epithelial cells. As observed in yeast, misfolded proteins, but not those that were properly folded, entered and lit up mitochondria.
Biological systems are in general quite robust, but there are also some Achilles’ heels that may be disease prone, Li says, and relying on the mitochondrial system to help with cleanup may be one such example. While young and healthy mitochondria may be fully up to the task, aged mitochondria or those overwhelmed by too much cleanup in troubled cells may suffer damage, which could then impair many of their other vital functions.
Other researchers involved in the study include Linhao Ruan, Erli Jin and Andrei Kucharavy, all of Johns Hopkins, as well as Chuankai Zhou, Zhihui Wen and Laurence Florens of Stowers Institute for Medical Research in Kansas City, Missouri. This work was funded by the National Institute of General Medical Science and the American Heart Association.
Ruan, L., Zhou, C., Jin, E., Kucharavy, A., Zhang, Y., Wen, Z., … Li, R. (2017). Cytosolic proteostasis through importing of misfolded proteins into mitochondria. Nature. doi:10.1038/nature21695
This article has been republished from materials provided by John Hopkins Medicine. Note: material may have been edited for length and content. For further information, please contact the cited source.
A team led by Johns Hopkins Medicine researchers says it has identified two protein biomarkers in urine that may one day be used to better diagnose acute interstitial nephritis, an underdiagnosed but treatable kidney disorder that impairs renal function in the short term and can lead to chronic kidney disease, permanent damage or renal failure if left unchecked.READ MORE
Researchers have pinpointed one specific group of bacteria, called Veillonella, that they found was enriched in the gut microbiome of Boston Marathon runners after completing the 26.2 mile race and in an independent group of 87 elite and Olympic athletes after competitions. Veillonella bacteria isolated from marathon athletes and given to mice increased the animals’ performances in laboratory treadmill tests by 13% compared to control bacteria.READ MORE