Molecules Dress for Success

The researchers have named these novel compounds “suitanes”, based on their resemblance to a torso with two or more limbs that is completely enveloped in a one-piece “suit”. The number of limbs is indicated by a number inserted into the name of the compound: A suit[2]ane has two limbs, a suit[3]ane has three limbs, and a suit[4]ane has four limbs. “A suit[5]ane looks like a doll wearing a one-piece romper enclosing all five limbs: two legs, two arms, and the head,” explains J. Fraser Stoddart, a pioneer of supramolecular chemistry.

The team headed by Stoddart (University of California, Los Angeles) and David J. Williams (Imperial College, London) have successfully synthesized the simplest representative of this class of compounds: a suit[2]ane. They first used computer simulations to develop a plan of attack. The inner molecule—the “body”—should be relatively stiff and oblong; the suit must be a flexible molecule that can be assembled around the body from a few individual components. Like a well-tailored suit, all of the individual components must be perfectly coordinated with each other regarding their shape, size, and functional groups.

The researchers first produced a stiff, linear molecular framework: a slim center (a central aromatic ring) is hooked to two bulging “shoulders” (anthracene ring systems), each in turn attached to an “arm”. Next, the molecule was dressed in its suit. The suit was put on piece by piece and “sewed” together in a final step: in a self-organization process, two large ring-shaped molecules (crown ethers) slipped like sleeves onto the molecular “arms”. The torso, arms, and sleeves were chemically outfitted to provide strong interactions to hold the sleeves tightly in place.

In the next step, another smaller type of molecule (aromatic ring) was added. These molecules each contained two groups of atoms (amino groups), located across from each other, designed to each enter into attractive interactions with one spot on each sleeve. In the final step, chemical bonds were formed at these four points of contact; the aromatic rings thus linked the two sleeves into a single large molecule that completely encloses the torso molecule without binding to it chemically.

"Discovering the way to dress a molecule with another one is a prelude to constructing artificial systems reminiscent of the living cell," says Stoddart.

Citation: J. Fraser Stoddart et al., Suitanes, Angewandte Chemie International Edition 2006, 45, No. 40, doi: 10.1002/anie.200602173

Source: Angewandte Chemie

Casting for molecules
Many of the larger molecules have something in common with dolls - movable limbs. Physicists at the Fritz Haber Institute of the Max Planck Society in Berlin can now sort molecules according to the direction in which their "arms" and "legs" point. Normally, it is almost impossible to distinguish between these conformers - molecules with different orientation - and, in any event, molecule limbs usually flap about wildly. Nevertheless, orientation is important for biomolecules: they can only do their job when they point their limbs in the right direction.
Clues to How Plants Form New Cell Walls Could Aid Biofuels, Nanotechnology
When plant cells divide, they assemble molecular building blocks into new cell walls made of carbohydrate and protein, but scientists know almost nothing about how this process occurs. A team of researchers including Maura Cannon of the University of Massachusetts Amherst has found that the first step in building new plant cell walls is the assembly of a scaffold made of structural proteins, a process similar to using a metal or wood scaffold to construct the walls of a building.
Stem cell research aims to tackle Parkinson's disease
Scientists in Sweden are developing new ways to grow brain cells in the laboratory that could one day be used to treat patients with Parkinson’s disease, an international conference of biologists organised by the European Science Foundation (ESF) was told last week.
Chemists develop new method for synthesizing anti-cancer flavonoids
Flavonoids. You’ve heard of them -- the good-for-your-health compounds found in plants that we enjoy in red wine, dark chocolate, green tea and citrus fruits. Mother Nature is an ace at making them, producing different ones by the thousands, but no chemist has figured out a good way to synthesize a special class of these chemicals in the laboratory. Until now.
Atomic-resolution views suggest function of enzyme that regulates light-detecting signals in eye
An atomic-resolution view of an enzyme found only in the eye has given researchers at the University of Washington (UW) clues about how this enzyme, essential to vision, is activated. The enzyme, phosphodiesterase 6 (PDE6), is central to the way light entering the retina is converted into a cascade of signals to the brain.
2008 ozone hole larger than last year
The 2008 ozone hole – a thinning in the ozone layer over Antarctica – is larger both in size and ozone loss than 2007 but is not as large as 2006.
Scripps Research scientists define structure of important neurological receptor
Scientists from The Scripps Research Institute have determined the structure of an adenosine receptor that plays a critical role in a number of important physiological processes including pain, breathing, and heart function. The findings could lead to the development of a new class of therapeutics for treating numerous neurological disorders, including Parkinson's and Huntington disease.
First glimpse of a key DNA repair protein at work
Repairing breaks in the two strands of the DNA double helix is critical for avoiding cancer. In humans and other organisms, a molecular machine called the MRN complex is responsible for finding and signaling double-strand breaks (DSBs), then launching the error-free method of DNA repair called homologous recombination.

Molecules Dress for Success

Related stories:

News discussion: