GPC Members Login
If you have any problems or have forgotten your login please contact [email protected]

Rare tree species safeguard biodiversity in a changing climate

New research suggests that rare species of trees in rainforests may help safeguard biodiversity levels as the environment undergoes change.

The study uses new methods of computer modelling to provide more accurate estimates of the number of tree species in large areas, which scientists have tested on data from real forests and found to be better than existing methods.

The research was conducted by a team from the University of Leeds, the University of Padua, the University of Oregon and the University of Maryland.

Dr Sandro Azaele, from the School of Mathematics at the University of Leeds, said: "Our new models can help predict the number of rare and unobserved species, a measure of fragile yet important biodiversity. We still do not know why the vast majority of Amazon tree species are so rare and only very few of them are very abundant. However, it's likely that hyper-rare species of trees, in places such as the Amazon Rainforest, are of great importance as the climate shifts, as some of them may become the common species of the future."

The new models, published in Science Advances, show that in 15 rainforests from across the globe, 50 per cent of the forest trees belong to a tiny number of species - the so-called hyper-dominants, which are made up of huge numbers of individuals. In contrast, the other 50 per cent is made up of many rare tree species, each of which is represented by a small number of individuals, but is poised to become the new dominant species if conditions change in their favour.

Led by Anna Tovo from the University of Padua, the research aims to provide a more accurate method of estimating biodiversity across large regions, in places such as the Amazon Rainforest where only 0.00016 per cent of the total area has been surveyed.

Dr Sandro Azaele, Lecturer in Applied Mathematics at the University of Leeds said: "Biodiversity helps provide support for life, vital provisions, regulating services and has positive cultural impacts. It is thus important to have accurate methods to measure biodiversity, in order to safeguard it when we discover it to be threatened. Our models are relevant for conservation because they allow us to quantify how many tree species face the most severe threats of extinction."

"We are in the midst of an extinction crisis," said Jayanth Banavar, provost and senior vice president at the University of Oregon and previously at the University of Maryland, "we are losing species perhaps more rapidly than ever before. These species have evolved over many, many millennia. A species once lost is gone forever."

Read the paper: Upscaling species richness and abundances in tropical forests.

Article source: University of Leeds.


New study shows producers where and how to grow cellulosic biofuel crops

According to a recent ruling by the United States Environmental Protection Agency, 288 million gallons of cellulosic biofuel must be blended into the U.S. gasoline supply in 2018. Although this figure is down slightly from last year, the industry is still growing at a modest pace. However, until now, producers have had to rely on incomplete information and unrealistic, small-scale studies in guiding their decisions about which feedstocks to grow, and where. A new multi-institution report provides practical agronomic data for five cellulosic feedstocks, which could improve adoption and increase production across the country.

Europe's lost forests: Coverage has halved over 6,000 years

More than half of Europe's forests have disappeared over the past 6,000 years thanks to increasing demand for agricultural land and the use of wood as a source of fuel, new research led by the University of Plymouth suggests.

The circadian clock sets the pace of plant growth

The recent award of the Nobel Prize in Physiology or Medicine to the three American researchers Hall, Rosbash and Young for their "discoveries of molecular mechanisms controlling the circadian rhythm" has greatly popularized this term -which comes from the Latin words "circa" (around of) and "die" (day)-. Thanks to the discoveries that these scientists did using the fruit fly, today we know that the organisms have an internal clock built of a set of cellular proteins whose amount oscillates in periods of 24 hours. These oscillations, which are autonomously maintained, explain how living organisms adapt their biological rhythm so that it is synchronized with the Earth's revolutions.