March 9, 2015
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Findings Could Help Shed Light on Alzheimer’s, Parkinson’s, ALS and Other Diseases
A team led by scientists at The Scripps Research Institute (TSRI) has determined the basic structural organization of a molecular motor that hauls cargoes and performs other critical functions within cells.
The new research provides the first picture of a molecular motor called the “dynein-dynactin complex,” which is critical for cell division and cargo transport. (Image courtesy of the Lander lab, The Scripps Research Institute.)
Biologists have long wanted to know how this molecular motor—called the “dynein-dynactin complex”—works. But the complex’s large size, myriad subunits and high flexibility have until now restricted structural studies to small pieces of the whole.
In the new research, however, TSRI biologist Gabriel C. Lander and his laboratory, in collaboration with Trina A. Schroer and her group at Johns Hopkins University, created a picture of the whole dynein-dynactin structure.
“This work gives us critical insights into the regulation of the dynein motor and establishes a structural framework for understanding why defects in this system have been linked to diseases such as Huntington’s, Parkinson’s, and Alzheimer’s,” said Lander.
The findings are reported in a Nature Structural & Molecular Biology advance online publication on March 9, 2015.
The proteins dynein and dynactin normally work together on microtubules for cellular activities such as cell division and intracellular transport of critical cargo such as mitochondria and mRNA. The complex also plays a key role in neuronal development and repair, and problems with the dynein-dynactin motor system have been found in brain diseases including Alzheimer’s, Parkinson’s and Huntington’s diseases, and amyotrophic lateral sclerosis (ALS). In addition, some viruses (including herpes, rabies and HIV) appear to hijack the dynein-dynactin transport system to get deep inside cells.
“Understanding how dynein and dynactin interact and work, and how they actually look, is definitely going to have medical relevance,” said Research Associate Saikat Chowdhury, a member of the Lander lab who was first author of the study.
To study the dynein-dynactin complex, Schroer’s laboratory first produced individual dynein and dynactin proteins, which are themselves complicated, with multiple subunits, but have been so highly conserved by evolution that they are found in almost identical form in organisms from yeast to mammals.
Chowdhury and Lander then used electron microscopy (EM) and cutting-edge image-processing techniques to develop two-dimensional “snapshots” of dynein’s and dynactin’s basic structures. These structural data contained unprecedented detail and revealed subunits never observed before.
Chowdhury and Lander next developed a novel strategy to purify and image dynein and dynactin in complex together on a microtubule—a railway-like structure, ubiquitous in cells, along which dynein-dynactin moves its cargoes.
“This is the first snapshot of how the whole dynein-dynactin complex looks and how it is oriented on the microtubule,” Chowdhury said.
Pushing the Limits
The structural data clarify how dynein and dynactin fit together on a microtubule, how they recruit cargoes and how they manage to move those cargoes consistently in a single direction.
Lander and Chowdhury now hope to build on the findings by producing a higher-resolution, three-dimensional image of the dynein-dynactin-microtubule complex, using an EM-related technique called electron tomography.
“The EM facility at TSRI is the best place in the world to push the limits of imaging complicated molecular machines like these,” said Lander.
The other co-author of the paper, Structural organization of the dynein–dynactin complex bound to microtubules, (doi:10.1038/nsmb.2996) was Stephanie A. Ketcham of the Schroer laboratory.
The research was supported by the Damon Runyon Cancer Research Foundation (DFS-#07-13), the Pew Scholars program, the Searle Scholars program and the National Institutes of Health (DP2 EB020402-01, GM44589).
See the full article here.
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The Scripps Research Institute (TSRI), one of the world’s largest, private, non-profit research organizations, stands at the forefront of basic biomedical science, a vital segment of medical research that seeks to comprehend the most fundamental processes of life. Over the last decades, the institute has established a lengthy track record of major contributions to the betterment of health and the human condition.
The institute — which is located on campuses in La Jolla, California, and Jupiter, Florida — has become internationally recognized for its research into immunology, molecular and cellular biology, chemistry, neurosciences, autoimmune diseases, cardiovascular diseases, virology, and synthetic vaccine development. Particularly significant is the institute’s study of the basic structure and design of biological molecules; in this arena TSRI is among a handful of the world’s leading centers.
The institute’s educational programs are also first rate. TSRI’s Graduate Program is consistently ranked among the best in the nation in its fields of biology and chemistry.