Collective excitations of germinating pollen grains at critical points

In plants, the germinating pollen grain (pollen tube) is a single, elongated cell that serves as a conduit through which gametes pass. Pollen tubes display a fast growth rate, which under certain conditions, changes periodically and is accompanied by ion exchange with the growth environment. Therefore, pollen tubes exposed to various abiotic conditions may adversely affect or improve their reproductive performance and fertility. We examined a collection of live pollen tubes of tobacco (Nicotiana tabacum L.) and hyacinth (Hyacinthus orientalis L.) using a non-invasive semiconductor-electrolyte interface technique in the vicinity of the germination temperature or optimum growth temperature of a pollen grains/tubes. The time series measurements and numerical calculations, performed using information theory methods, represent signatures of collective dynamics in living cells at critical-molecularly encoded-germination and growth temperatures. This method (and soil pH data) can facilitate assisted plant migrations from one ecosystem to another as the Earth faces climate change.

Automated summary

Through the study of tobacco and hyacinth pollen tubes, it was found that time series measurements and numerical calculations using information theory methods represent signatures of collective dynamics in living cells at critical-molecularly encoded-germination and growth temperatures. This method, along with soil pH data, can facilitate assisted plant migrations from one ecosystem to another as the Earth faces climate change.