It's an emergency! Interview with Gesa Zander on cellular response to heat stress!

Imagine a sudden crisis within a country. One day, suddenly, there is a need to face an impending disaster. What happens? The people go into panic-mode and stop doing their regular jobs, and instead focus on averting the crisis. Normal production ceases, and things needed to face the disaster are produced. The pace of production is ramped, and irrespective of the quality, a huge quantity of emergency supplies is generated.

Like humans, cells in our body also face crisis. They need to adapt to extreme environments quickly in order to survive and thrive. Gesa, Alexandra, Lysann and colleagues wanted to know what happens to the cellular production process during the stress period. How does the cell switch to producing cell-responsive genes. And not only producing, but producing at a fast-pace. Are the quality controls applicable during normal times also applicable during the frantic response to stress. They find that the cell switches to stress-control mode, and for a certain time, eases on the quality controls of production. Please listen to Gesa on the interesting adaptability of the cells.


For more information, please refer to:
mRNA quality control is bypassed for immediate export of stress-responsive transcripts
Zander et al., Nature, 2016

A Time to Spring! Interview with Julia Qüesta on cold sensation in plants!!

Winter ends and the layer of snow clears off the ground. The soil is fresh for new cycle of vegetation. It instantly converts to a beautiful expanse of flowers and fresh plants. How does such a drastic change occur? How did the plants 'know' the change in seasons. They don't have an almanac or the weather channel to tell them of the ending cold, or do they??

Julia and colleagues undertook to understand the sensing of winter-to-spring transformation in plants. It is possibly the most important decision for the survival of the plant. Arising anew from winter needs to be perfectly timed. A little early, and the frosty cold will chill the new life. A little late and the other plants would have taken away precious space and resources, making it difficult to fight for survival. And importantly, its a one time event: an on-off switch. The plant needs to integrate a million parameters into a single result. An elaborate chain of events culminating into a life or death choice.

How does the switch operate? Julia and colleagues map the system to basepair resolution by finding the machinery and its corresponding binding sites on the plant genome for controlling the process. This amazing feat (for plant and the team) is a perfect example of how simplicity underlies complex decision making. To understand more, please listen to Julia.



To know more, please refer to:
Arabidopsis transcriptional repressor VAL1 triggers Polycomb silencing at FLC during vernalization.
Qüesta et al., Science 2016.

Colonizing Mars! Lessons on avoiding inbreeding issues from flatworms by Longhua Guo!

Imagine the year 2500. We have chosen twenty of our best and brightest to send to Mars. They have the mission to start a human colony there. Of-course that would mean breeding and generating more humans. But with only 20 people, the population might be genetically too small. Creating babies from genetically similar individuals, like cousins, can lead to birth defects. Within a few populations, intermixing might doom the entire project, just like inbreeding doomed the once powerful Habsburg Dynasty. How can we avoid this?

The question is not only critical to our hypothetical journey to Mars, but also to survival of critically endangered species. Very few individuals of hawksbill turtle, tigers and many other remain. How can we avoid in-breeding defects in such animals in near future. The answer to that might lie in the champions of regeneration, freshwater planarians. Planarians are known for their amazing capacity to regenerate a full animal from any part of their body. But also, as Longhua and colleagues found out, can avoid their genome from becoming similar after multiple rounds of in-breeding. How can these animals achieve such feat, please listen to Longhua to know more:


For more information, please refer to:
Widespread maintenance of genome heterozygosity in Schmidtea mediterranea.
Guo L., et al., Nature Ecology & Evolution, 2016.

Further information can be found here:
The joy of figuring things out: a story of worms, haplotypes & genetic ancestry.