Structure of Neuron-Connecting Synaptic Adhesion Molecules Discovered

Figure 1: Overview of the PTPd Ig1–3/Slitrk1 LRR1 complex. Copyright : Korea Advanced Institute of Science and Technology

A research team has found the three-dimensional structure of synaptic adhesion molecules, which orchestrate synaptogenesis. The research findings also propose the mechanism of synapses in its initial formation.

Some brain diseases such as obsessive compulsive disorder (OCD) or bipolar disorders arise from a malfunction of synapses. The team expects the findings to be applied in investigating pathogenesis and developing medicines for such diseases.

The research was conducted by a Master’s candidate Kee Hun Kim, Professor Ji Won Um from Yonsei University, and Professor Beom Seok Park from Eulji University under the guidance of Professor Homin Kim from the Graduate School of Medical Science and Engineering, Korea Advanced Institute of Science and Technology (KAIST), and Professor Jaewon Ko from Yonsei University. Sponsored by the Ministry of Science, ICT and Future Planning and the National Research Foundation of Korea, the research findings were published online in the November 14th issue of Nature Communications.

Figure 2: Representative negative-stained electron microscopy images of Slitrk1 Full ectodomain (yellow arrows indicate the horseshoe-shaped LRR domains). The typical horseshoe-shaped structures and the randomness of the relative positions of each LRR domain can be observed from the two-dimensional class averages displayed in the orange box. Copyright : Korea Advanced Institute of Science and Technology

A protein that exists in the neuronal transmembrane, Slitrk, interacts with the presynaptic leukocyte common antigen-related receptor protein tyrosine phosphatases (LAR-RPTPs) and forms a protein complex. It is involved in the development of synapses in the initial stage, and balances excitatory and inhibitory signals of neurons.

It is known that a disorder in those two proteins cause a malfunction of synapses, resulting in neuropsychosis such as autism, epilepsy, OCD, and bipolar disorders. However, because the structure as well as synaptogenic function of these proteins were not understood, the development of cures could not progress.

The research team discovered the three-dimensional structure of two synaptic adhesion molecules like Slitrk and LAR-RPTPs and identified the regions of interaction through protein crystallography and transmission electron microscopy (TEM). Furthermore, they found that the formation of the synapse is induced after the combination of two synaptic adhesion molecules develops a cluster.

Figure 3: Model of the two-step presynaptic differentiation process mediated by the biding of Slitrks to LAR-RPTPs and subsequent lateral assembly of trans-synaptic LAR-RPTPs/Slitrik complexes. Copyright : Korea Advanced Institute of Science and Technology

Professor Kim said, “The research findings will serve as a basis of understanding the pathogenesis of brain diseases which arises from a malfunction of synaptic adhesion molecules. In particular, this is a good example in which collaboration between structural biology and neurobiology has led to a fruitful result.” Professor Ko commented that “this will give new directions to synaptic formation-related-researches by revealing the molecular mechanism of synaptic adhesion molecules.”

Source: KAIST

What bank voles can teach us about prion disease transmission and neurodegeneration

This image shows accumulation of misfolded, toxic prion protein (brown staining) in the brain of a transgenic mouse expressing bank vole PrP and challenged with human variant Creutzfeldt-Jakob disease (vCJD) prions. Credit: Image courtesy of Dr. Joel Watts

When cannibals ate brains of people who died from prion disease, many of them fell ill with the fatal neurodegenerative disease as well. Likewise, when cows were fed protein contaminated with bovine prions, many of them developed mad cow disease. On the other hand, transmission of prions between species, for example from cows, sheep, or deer to humans, is -- fortunately -- inefficient, and only a small proportion of exposed recipients become sick within their lifetimes.

A study published on April 3rd in PLOS Pathogens takes a close look at one exception to this rule: bank voles appear to lack a species barrier for prion transmission, and their universal susceptibility turns out to be both informative and useful for the development of strategies to prevent prion transmission.
Prions are misfolded, toxic versions of a protein called PrP, which in its normal form is present in all mammalian species that have been examined. Toxic prions are "infectious"; they can induce existing, properly folded PrP proteins to convert into the disease-associated prion form. Prion diseases are rare, but they share features with more common neurodegenerative diseases like Alzheimer's disease.

Trying to understand the unusual susceptibility of bank voles to prions from other species, Stanley Prusiner, Joel Watts, Kurt Giles and colleagues, from the University of California in San Francisco, USA, first tested whether the susceptibility is an intrinsic property of the voles' PrP, or whether other factors present in these rodents make them vulnerable.

The scientists introduced into mice the gene that codes for the normal bank vole prion protein, thereby generating mice that express bank vole PrP, but not mouse PrP. When these mice get older, some of them spontaneously develop neurologic illness, but in the younger ones the bank vole PrP is in its normal, benign folded state. The scientists then exposed young mice to toxic misfolded prions from 8 different species, including human, cattle, elk, sheep, and hamster.

They found that all of these foreign-species prions can cause prion disease in the transgenic mice, and that the disease develops often more rapidly than it does in bank voles. The latter is likely because the transgenic mice express higher levels of bank vole PrP than are naturally present in the voles.

The results show that the universal susceptibility of bank voles to cross-species prion transmission is an intrinsic property of bank vole PrP. Because the transgenic mice develop prion disease rapidly, the scientists propose that the mice will be useful tools in studying the processes by which toxic prions "convert" healthy PrP and thereby destroy the brain. And because that process is similar across many neurodegenerative diseases, better understanding prion disease development might have broader implications.

Source:  PLOS