Statins, other cholesterol depletors, may disrupt hypertension development: UCSD study

April 03, 2005

San Diego (April 3, 2005) - Cholesterol-lowering agents, such as the widely-prescribed statin drugs, and cholesterol-blocking agents may prove to be "novel therapeutic agents to modify cellular calcium that contributes to the development of pulmonary hypertension," according Hemal H. Patel who lead a multidisciplinary team of researchers at the University of California, San Diego (UCSD).

In studying idiopathic pulmonary hypertension (PPH), formerly called primary pulmonary hypertension, the UCSD team found "a previously unappreciated cellular and molecular mechanism for the disease process," Patel said, "which may be amenable to treatment with current and future therapies and might provide more substantial, long-term and efficacious benefit to those that have IPAH."

Patel is presenting the research at the 35th Congress of the International Union of Physiological Sciences in San Diego, March 31 - April 5, 2005.

*Paper presentation: "Cholesterol-depleting drugs, including statins, lower intracellular Ca2+ and inhibit proliferation in pulmonary artery smooth muscle cells in primary pulmonary hypertension," 12:30 p.m.-3 p.m. Tuesday April 5, Physiology 933.6/board #A446. On view 7:30 a.m. - 4 p.m.

*Featured topic: Patel will participate in Session 898, "Overview: From organelles to organ," a featured topic of the IUPS Calcium Signaling Track, Tuesday beginning at 10:30 a.m., Convention Center room 29C. Patel's presentation is scheduled for noon.

All researchers involved in the study are from UCSD: Hemal H. Patel, Fiona Murray and Paul A. Insel, Department of Pharmacology; Shen Zhang and Jason X-J Yuan, Dept. of Medicine, and Patricia A. Thistlethwaite, Dept. of Surgery.

Research aimed at cellular calcium-dependent aspects of hypertension

IPAH is a severe clinical disease. The prognosis of PPH is poor with untreated disease leading to heart failure and death in two to eight years, Patel noted. Because of limited understanding of the cellular and molecular determinants of the disease process, current therapy is limited and aimed towards symptomatic relief.

He said two factors that contribute to the disease are dependent on cellular calcium: constriction of vessels, and uncontrolled cell growth resulting in thickening of vessels. "We sought to determine, 1.) if IPAH has altered caveolae, which in Latin means "little caves," on the membrane composed of cholesterol that control the intake of calcium into cells, and 2.) if agents that modify cellular cholesterol might limit calcium intake and ultimately limit the two factors (constriction and growth) in vessels that contribute to the disease process. These drugs then might provide for a novel therapy that not merely provides temporary relief of disease symptoms, but helps alleviate the underlying cause of IPAH," Patel explained.

Lovostatin, MBCD significantly reduce calcium entry, cut cell proliferation

In their research, the team saw that "smooth muscle cells isolated from pulmonary arteries of patients with IPAH indeed had more caveolae on the cell membrane compared to cells from normal individuals, and also that there was a higher calcium intake into the diseased cells," Patel reported. Subsequent treatment of the IPAH cells with an agent that depletes cholesterol (methyl-beta-cyclodextrin, or MBCD), or "a statin (in this case, lovostatin, sold as Mevacor by Merck), which blocks cholesterol synthesis, resulted in a disruption of the caveolae and reduced the amount of calcium that entered the cells.

"Additionally, these two treatments also decreased the growth rate of the diseased cells," Patel said. Taken together, the results "mean that the micro-structure of the cell membrane is involved in controlling the intake of calcium and that the cholesterol modifiers of these structures may serve as novel therapeutics to reduce vessel constriction and cell growth associated with increased calcium intake in IPAH," Patel stated.

Next steps: Determine caveolae proteins and how they influence calcium intake

The next steps, Patel explained, are to understand the nature of the proteins located on the caveolae and how these structures communicate with the internal regions of cells to influence calcium intake into the cell. He said the UCSD researchers "already have begun looking at the expression and localization of ion channels into caveolae that may further explain the increased calcium intake into cell."
-end-
Funding. The research in the study was supported by the National Institutes of Health.

The 35th Congress of the International Union of Physiological Sciences is in San Diego, March 31 - April 5, 2005. The Congress (http://www.iups2005.org/) is organized by the six member societies of the U.S. National Committee of the IUPS, the American Physiological Society, the Society for Neuroscience, the Microcirculatory Society, the Society of General Physiologists, the Biomedical Engineering Society, and the Society for Integrative and Comparative Biology, under the auspices of the U.S. National Academy of Sciences.

The IUPS conference, held every four years, runs concurrently this year with Experimental Biology 2005 at the San Diego Convention Center.

The American Physiological Society (APS), which is hosting IUPS, was founded in 1887 to foster basic and applied science, much of it relating to human health. The Bethesda, MD-based Society has more than 10,000 members and publishes nearly 4,000 articles every year in its 14 peer-reviewed journals. In May, APS received the Presidential Award for Excellence in Science, Mathematics and Engineering Mentoring (PAESMEM).

Editor's Note: For further information or to schedule an interview with a member of the research team, please contact Mayer Resnick at the IUPS/APS newsroom @ 619.525.6228 (March 31-April 6), or 301.332.4402 (cell) or 301.634.7209 (office), or Stacy Brooks at 240.432.9697 (cell) or 301.634.7253 (office).

A searchable online program for IUPS and EB is at http://www.faseb.org/meetings/eb2005/call/default.htm

IUPS/APS Newsroom March 29-April 6
San Diego Convention Center
Hall E Registration Area/Flex Unit
Telephone: 619.525.6228

American Physiological Society

Related Cholesterol Articles from Brightsurf:

Cholesterol's effects on cellular membranes
The findings have far-reaching implications in the general understanding of disease, the design of drug delivery methods, and many other biological applications that require specific assumptions about the role of cholesterol in cell membranes.

Autism-cholesterol link
Study identifies genetic link between cholesterol alterations and autism.

Microbes might manage your cholesterol
Researchers discover a link between human blood cholesterol levels and a gene in the microbiome that could one day help people manage their cholesterol through diet, probiotics, or entirely new types of treatment.

Experimental cholesterol-lowering drug effective at lowering bad cholesterol, study shows
Twice-yearly injections of an experimental cholesterol-lowering drug, inclisiran, were effective at reducing low-density lipoprotein (LDL) cholesterol, often called bad cholesterol, in patients already taking the maximum dose of statin drugs, according to data of the ORION-10 trial presented Saturday, Nov.

Rethinking how cholesterol is integrated into cells
Cholesterol is best known in connection with cardiovascular disease, but cholesterol is also vital for many fundamental processes in the body.

Seed oils are best for LDL cholesterol
Using a statistical technique called network meta-analysis, researchers have combined the results of dozens of studies of dietary oils to identify those with the best effect on patients' LDL cholesterol and other blood lipids.

Cholesterol leash: Key tethering protein found to transport cellular cholesterol
Cholesterol is an essential component of living organisms, but the mechanisms that transport cholesterol inside the cell are poorly understood.

New way to treat cholesterol may be on the horizon
A breakthrough discovery by scientists at Houston Methodist Research Institute could change the way we treat cholesterol.

How low should LDL cholesterol go?
New analysis shows that in a high-risk population, achieving ultra-low LDL cholesterol levels, down to <10 mg/dL, safely results in additional lowering of risk of cardiovascular events.

Does boosting 'good' cholesterol really improve your health?
A new review addresses the mysteries behind 'good' HDL cholesterol and why boosting its levels does not necessarily provide protection from cardiovascular risk for patients.

Read More: Cholesterol News and Cholesterol Current Events
Brightsurf.com is a participant in the Amazon Services LLC Associates Program, an affiliate advertising program designed to provide a means for sites to earn advertising fees by advertising and linking to Amazon.com.