兔子先生传媒文化作品

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Physics sheds new light on cellular biology

Physics sheds new light on cellular biology

兔子先生传媒文化作品 PhD gets prize for top thesis in biological physics

 

Turns out, it took a physicist to unlock some key findings about how cells actually divide, and Robert Blackwell, who recently received his PhD in biological physics from the University of Colorado Boulder, apparently stepped up to the plate in a big way.

In January, Blackwell found out the American Physical Society had chosen his PhD thesis, "Physical determinants of bipolar mitotic spindle assembly and stability in fission yeast,鈥 as the Outstanding Doctoral Thesis Research in Biological Physics for the year.

Blackwell, who is currently doing postdoctoral work on membranes and motor proteins at Friedrich-Alexander University in Germany, said he wasn鈥檛 totally surprised by the award, but was very happy nonetheless.

鈥淚 was a little surprised鈥擨鈥檝e never won anything before,鈥 he said. 鈥淣ow, I鈥檓 in very good company (with past winners of the award). Biological physics has been around for around 60 years, but it鈥檚 coming to maturation now, and I had a lot of help at CU from some very talented scientists.鈥

Blackwell

Robert Blackwell

Blackwell鈥檚 findings have some fundamental applications in microbiology as it addresses a key transition in mitosis, and some potentially life-saving long-term pathways in cancer treatment. To get there, he based his research on yeast cells, one of the simplest single-celled organisms on Earth.

鈥淎ll cells have to divide to sustain life,鈥 and to do so they need to share the DNA with the two daughter cells, Blackwell said. 鈥淭hey grow these long tubes (known as microtubules) that grab the DNA, and this structure is known as the mitotic spindle.鈥

鈥淲e knew what the building blocks were, but not how they interacted,鈥 Blackwell said. 鈥淚n our research, we detail how the forces inside the spindle balance each other out.鈥

In a cellular context, Blackwell described these spindles as growing and shrinking 鈥渋ron girders,鈥 and while they are created by various proteins, the active cross-linking proteins, or motors, were shown to interact more dynamically than previously thought. In particular, the research focused on one of these motors, known as kinesin-5, which is extremely important to the dynamics governing the spindle creation, polarity and eventually the division that passes the DNA information to the daughter cells.

鈥淚t was thought always to always walk up to the middle of the spindle, but sometimes it walks back,鈥 Blackwell said. 鈥淲e find that this backward motion is necessary for the spindles to form.鈥

鈥淭he work had a lot of findings,鈥 he continued. But most importantly, 鈥渨e can have a model that can describe the spindle formation from the ground up.鈥

Blackwell鈥檚 modeling of the 2.5-micrometer spindles is based on physical measurements conducted by high-powered microscopic cameras and electron microscopy. Though human cells are probably 1,000 times more complex in their spindle construction, Blackwell believes his model will help in identifying chemical means to alter spindle creation.

From a standpoint of combating cancer through chemotherapy such, modeling could identify protein combinations, rather than the conventional single proteins, that could be inhibited. Treating these protein combinations could potentially increase the efficacy of drugs and reduce their side effects.

Those are tangible results for Blackwell, a physicist who only turned to microbiology after deciding against following more abstract fields such as astrophysics or string theory.

鈥淚鈥檝e wanted to be a physicist since I was 16, and I guess I am,鈥 said Blackwell, who has now branched out into researching the physical dynamics of cell membranes. 鈥淚鈥檝e always told my students how important it is to approach research across disciplines.鈥