April 23, 2018
Biologists discover new and unique cell-signalling mechanism in plants
Riley Brandt, 草莓污视频导航
Biologists in the Faculty of Science have discovered a new and unique, enzyme-controlled cell-signalling mechanism in plants, which enhances understanding of how cells in all living organisms communicate with each other.
Research teams led by Greg Moorhead and Ken Ng at the 草莓污视频导航 investigated an enzyme named RLPH2, first identified by Moorhead鈥檚 research group.
RLPH2 is a protein phosphatase, a group of enzymes that catalyze a vital chemical reaction, called dephosphorylation, in cells.
In a multidisciplinary collaboration between biochemistry and structural biology, the teams discovered that RLPH2 carries out dephosphorylation in an unusual and previously unknown way.
Protein phosphorylation regulates most aspects of cell life. It is the "conductor" that orchestrates the sending and interpreting of messages within and between cells, by chemically altering thousands of proteins within cells.
This is the dominant way that cells in all living organisms, including humans, communicate in controlling many activities inside cells 鈥 and thereby the physiological outcomes in plants, animals and other organisms.
The research teams found that the RLPH2 enzyme has an unusually deep active site structure, with two different 鈥減hospho-binding鈥 sites where the enzyme chemically binds with a 鈥渟ubstrate鈥 (a molecule upon which the enzyme acts). RLPH2鈥檚 two sites include a novel secondary phospho-binding "pocket."
鈥淭his enables RLPH2 to carry out very specific dephosphorylation via a dual mechanism, recruiting substrates through the secondary pocket, then ultimately dephosphorylating a nearby amino acid called phosphotyrosine,鈥 says Moorhead, professor of biochemistry in the .
鈥淭he uniqueness of this enzyme is the tyrosine dephosphorylation and the secondary binding pocket, which is completely unique for this group of enzymes,鈥 he says.
鈥淭he deeper active site structure allows the enzyme to uniquely recognize the phosphotyrosine, which 鈥榬eaches鈥 into the active site,鈥 says Ng, professor of structural biology in the Department of Biological Sciences.
The team鈥檚 , 鈥淪tructural Basis for the Preference of the Arabidopsis thaliana Phosphatase RLPH2 for Tyrosine-phosphorylated Substrates,鈥 is published in Science Signaling, a journal in the top-ranked Science series.
Cell signalling involved in major human diseases
Cell signalling activated by protein phosphorylation is a "hot" research topic. Abnormal protein phosphorylation is a cause or consequence of major diseases, such as cancer, diabetes and rheumatoid arthritis.
Also, defects in genes that encode the enzymes (protein kinases and phosphatases) involved in phosphorylation underlie several inherited and acquired disorders, such as leukemias, lymphomas and immune diseases.
Almost every large pharmaceutical company and many biotechnology firms are targeting protein kinases and protein phosphatases in developing therapies for diseases, particularly cancers. Such applications wouldn鈥檛 be possible without first thoroughly understanding signal transduction and phosphorylation.
鈥淲e want to understand all of the protein kinases and phosphatases inside a cell and how they work in each signalling pathway 鈥 that鈥檚 the ultimate goal,鈥 Moorhead says.
Revealing the RLPH2 enzyme鈥檚 structure
The researchers used bioinformatics, or genome sequencing analysis, to first pinpoint the RLPH2 enzyme, which exists in plants but not in animals.
Moorhead鈥檚 team performed the gene cloning and the protein expression (producing the RLPH2 enzyme) and the enzyme assays.
Much of this biochemistry work was done by Anne-Marie Labandera, then a PhD student with Moorhead, and the lead author on the new paper. She鈥檚 now in the U.K. doing post-doctoral work at the University of Birmingham.
鈥淓mploying a multidisciplinary approach on my PhD was key to characterize this unique plant protein and to understand its atypical behaviour,鈥 Labandera says.
The researchers expected RLPH2 would 鈥 like other enzymes in the same group 鈥 biochemically target and dephosphorylate phosphoserine and phosphothreonine. These are the two amino acid residues most commonly involved in protein phosphorylation.
To their surprise, RLPH2 preferred to target phosphotyrosine. Tyrosine is involved in only about two per cent of protein phosphorylation in living organisms.
鈥淏ased on genomics, there鈥檚 only one known tyrosine phosphatase in plants,鈥 Moorhead says. 鈥淪o I think this RLPH2 enzyme is really important to add to that group, and in part explains this lack of tyrosine phosphatases in plants because this other enzyme has been adapted to play that role.鈥
Ng and his team used the protein produced by Moorhead鈥檚 laboratory to grow microscopic-sized crystals. They then shone X-rays on the crystals, from which they mathematically calculated RLPH2鈥檚 3-D structure 鈥 down to individual molecules.
鈥淭he structure tells us how this enzyme is able to recognize some little piece of a protein and do its activity on just that,鈥 Ng says.
Collaboration key to the discovery
The unique specificity of RLPH 2 suggests it controls the activity of one or more of a group of important enzymes in the cell called mitogen activated protein kinases, or MAPKs, Moorhead says. 鈥淭he MAPK enzymes receive information from a variety of sources, perpetuating the signal and allowing the cell to respond appropriately to the information being sent.鈥
Without the collaboration between the biochemistry and structural biology teams, 鈥渢his discovery wouldn鈥檛 have happened,鈥 Moorhead says.
Labandera agrees, saying: 鈥淭hanks to this collaboration with Prof. Ng, we figured out the necessary features that RLPH2鈥檚 targets need to possess, for ultimately understanding its physiological relevance.鈥
Adds Ng: 鈥淭he strength of the Faculty of Science is we鈥檙e all very interested in these fundamental research questions. And from this fundamental research, you can鈥檛 tell 鈥 10, 20 or 30 years later 鈥 where the big applications will come.鈥
The teams鈥 research was supported by the .