A new mode of action for enzymes immersed in cellular membranes:
How and What…??
In a report published online Nov. 13 in the new journal eLife,
the Johns Hopkins scientists say their study results are the first to shed
light on how these enzymes make use of their native environment to function.
The particular "cellular scissors" that they studied, known as
rhomboid proteases, are unusual among proteases because they cut their target
proteins from inside cellular membranes. And because these and other membrane
proteases have roles to play in everything from malaria to Parkinson's disease,
uncovering their "inside" work could have profound implications for
human health, the scientists note.
"The evolution of these proteases, which are found in all types
of living organisms, gave cells a whole new set of tools for regulating
biology," says principal investigator Sinisa Urban, Ph.D., associate
professor of molecular biology and genetics at the Institute for Basic
Biomedical Sciences at Johns Hopkins.
Proteases cut proteins for many reasons. The stomach relies on
them to indiscriminately break down and digest various proteins people eat.
Other proteases are more specialized and help regulate the immune system, for
example. Each of these specialized proteases recognizes only specific protein
"clients" and only cuts its clients at one specific site.
"Until we did this work, it was thought that specialized
proteases decided which proteins to cut based on the presence or absence of a
specific sequence of amino acids they recognized," says Urban. "But
while most proteases work in watery environments, rhomboid proteases work in
oily membranes. Their unique environment suggested to us that they may also
have unique properties within the cell."
Urban notes that rhomboid proteases are like barrels with a gate
that only allows certain proteins inside. Once proteins get past the gate, they
interact with the "scissors" inside the barrel and get clipped and
released.
For their research, Urban and his team analyzed the activity of
rhomboid proteases in microscopic gel-like droplets, which are traditionally
used as substitutes for cell membranes, but which are incomplete imitations. To
more thoroughly assess the role of the protease's environment in its function,
they also developed ways to reassemble rhomboid proteases and their clients in
real cell membranes. This allowed them to use cutting-edge biophysical
techniques to compare how the enzymes and clients behaved in real membranes
versus membrane substitutes.
They report that rhomboid proteases allow more proteins through
their gates -- and cut them at different places -- when they are in the gel
than when they are in the membrane. "That told us that these proteases are
less accurate in recognizing which proteins to cut in the artificial
environment than in their natural one," says Urban. "The membrane
clearly helps to keep the gate from swinging open and letting unnatural sites
to be cut."
The researchers then took a series of different proteins and
changed their makeups in a variety of ways to see which ones the rhomboid
proteases could cut in living cells. By analyzing dozens of individual changes
to various proteins, they found that specific sequences were not the main thing
that determined which proteins were cut. Instead, the key factor was whether
the protein target was unstable in a watery environment.
Urban explains that when a protein contains a segment that crosses
the viscous, oily cell membrane, that segment takes on a curly cue shape, like
a slinky, even if it's floppy and shapeless outside the membrane in a watery
environment. "Rhomboid proteases have watery inner chambers. If the slinky
shape falls apart inside, the protein gets cut. If the slinky shape remains
intact, it doesn't get cut."
This insight, says Urban, opens possibilities for better
understanding several diseases and ultimately for developing treatments. For
example, he says, the protein that builds up in the brain of Alzheimer's
patients is a target for another type of membrane-resident protease that isn't
well understood either.
Co-authors of the report are Syed Moin and Sinisa Urban from the
Johns Hopkins University School of Medicine and the Howard Hughes Medical
Institute.
The research was supported by grants from the National Institute
of Allergy and Infectious Diseases (AI066025) and the Howard Hughes Medical
Institute.
Journal Reference:
1. Syed M Moin, Sinisa Urban. Membrane
immersion allows rhomboid proteases to achieve specificity by reading
transmembrane segment dynamics. eLife, 2012; 1 DOI: 10.7554/eLife.00173
Source:
The above story is reprinted from materials provided
by Johns Hopkins Medicine.
Note: Materials may be edited for content and length.
For further information, please contact the source cited above
Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of Eagle Group or its staff.
Disclaimer: This article is not intended to provide medical advice, diagnosis or treatment. Views expressed here do not necessarily reflect those of Eagle Group or its staff.
Written by Unknown
We are Creative Blogger Theme Wavers which provides user friendly, effective and easy to use themes. Each support has free and providing HD support screen casting.
0 comments:
Post a Comment