Identified as a «priority eye disease» by the World Health Organization, cataracts — caused when the lenses of the eyes lose their transparency — affect more than 20 million people worldwide. Although cataracts can be successfully removed with surgery, this approach is expensive, and most individuals blinded by severe cataracts in developing countries go untreated.
Reported Nov. 5 in Science, the newly identified compound is the first that is soluble enough to potentially form the basis of a practical
Cataracts are primarily a disease of aging. As is seen in neurodegenerative conditions such as Alzheimer’s disease and Parkinson’s disease, a hallmark of the condition is the misfolding and clumping together of crucial proteins. In the case of cataracts, the affected proteins are known as crystallins.
Crystallins are the major component of fiber cells, which form the eyes’ lenses, and the unique properties of these cells make them particularly susceptible to damage, said Jason Gestwicki, PhD, associate professor of pharmaceutical chemistry at UCSF and
«Shortly after you’re born, all the fiber cells in the eye lose the ability to make new proteins, or to discard old proteins," said Gestwicki, who has continued his work on cataracts at UCSF, where he joined the faculty about two years ago. «So the crystallins you have in your eye as an adult are the same as those you’re born with.»
In order for our lenses to function well, this permanent, finite reservoir of crystallins must maintain both the transparency of fiber cells and their flexibility, as the eyes’ muscles constantly stretch and relax the lens to allow us to focus on objects at different distances.
The crystallins accomplish these duties with the help of aptly named proteins known as chaperones, which act «kind of like antifreeze," Gestwicki said, «keeping crystallins soluble in a delicate equilibrium that’s in place for decades and decades.»
This
Lowering the Melting Point of Amyloids
In the new study, led by Leah N. Makley, PhD, and Kathryn McMenimen, PhD, the scientific team exploited a crucial difference between properly folded crystallins and their amyloid forms: put simply, amyloids are harder to melt.
The research group used a method known as
Because the melting point of amyloids is higher than that of normal crystallins, the team focused on finding chemicals that lowered the melting point of crystallin amyloids to the normal, healthy range.
The group began with 2,450 compounds, eventually zeroing in on 12 that are members of a chemical class known as sterols. One of these, known as lanosterol, was shown to reverse cataracts in a July paper in Nature, but because lanosterol has limited solubility, the group who published that study had to inject the compound into the eye for it to exert its effects.
Using lanosterol and other sterols as a clue, Gestwicki and his group assembled and tested 32 additional sterols, and eventually settled on one, which they call «compound 29," as the most likely candidate that would be sufficiently soluble to be used in
In laboratory dish tests, the team confirmed that compound 29 significantly stabilized crystallins and prevented them from forming amyloids. They also found that compound 29 dissolved amyloids that had already formed. Through these experiments, said Gestwicki, «we are starting to understand the mechanism in detail. We know where compound 29 binds, and we are beginning to know exactly what it’s doing.»
Testing as Eye Drops
The team next tested compound 29 in an
Similar results were seen when compound 29 eye drops were applied in mice that naturally developed
Gestwicki cautions that
Application for Cataracts and Beyond
Dogs are also prone to developing cataracts. Half of all dogs have cataracts by nine years of age, and virtually all dogs develop them later in life. An effective
ViewPoint was formed through the «incubator» program of the California Institute of Quantitative Biosciences (QB3) at UCSF, and is located adjacent to the UCSF campus in QB3’s Janssen Labs.
McMenimen, also a former graduate student in the Gestwicki laboratory, is now the Claire Boothe Luce Assistant Professor of Chemistry at Mt. Holyoke College. The research was supported by the National Institutes of Health, the American Foundation for Pharmaceutical Education, and Research to Prevent Blindness.
In addition to compound 29’s potential for cataract treatment, the insights gained through the research could have broader applications, said Gestwicki, a member of UCSF’s Institute for Neurodegenerative Diseases whose main research interest is dementia and related disorders.
«If you look at an electron micrograph at the protein aggregates that cause cataracts, you’d be
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