The nature of three ancient woodland soils in southern England

Abstract. Despite a wealth of published research on the nature of woodland soils, little is known about the nature of soils on sites that have supported woodland for many hundreds of years, namely ancient woodland. The properties and variability of soils in three ancient woods; one in the New Forest, Hampshire and two in Berkshire, were compared with those under recent woods. The acidity of ancient and recent woodland soils was high and remarkably similar. Only where cultivation of soils had preceded woodland establishment was soil acidity lower. The quantity of carbon in the soils studied was inversely related to soil acidity and the ancient woods had accumulated larger quantities of carbon than their recent counterparts. The quantities of Ca²⁺, Mg²⁺ and K⁺ were larger in the ancient woods except where prior cultivation had taken place. Total and organic phosphate contents of the ancient woodland soils were also consistently larger. The nature and pattern of soil variability in ancient woodland soils was quite distinct from that found in recent woods. Overall, the variability of soil acidity, carbon content and organic phosphate was larger in the ancient woodland soils but the pattern of variability differed between the soil properties. No clear association existed between the pattern of soil acidity and individual trees. At the surface of some of the woodland soils, however, carbon distribution appeared to be associated with individual trees. At depth in the ancient woodland soils, the association with the existing vegetation cover was not so clear. It is probable that the ancient woodland soils retained relict features of previous vegetation cover. Organic phosphate distribution was very strongly associated with the present vegetation cover. The pattern of distribution of organic phosphate appeared to be stronger than that of soil acidity and carbon content.     

Transkingdom transfer of the phosphoglucose isomerase gene

Previous analysis of the gene encoding phosphoglucose isomerase (Pgi) suggests that this gene may have been transferred between a eukaryote and a bacterium. However, excluding the alternative hypothesis of ancient gene duplication has proven difficult because of both insufficient sampling of taxa and an earlier misidentification of a bacterialPgi sequence. This paper presents a phylogenetic analysis of published completePgi sequences together with analysis of new partialPgi sequences from six species of bacteria. The data identify a group of bacterialPgi sequences, including sequences fromEscherichia coli andHaemophilus influenzae, which are more closely related to eukaryoticPgi sequences than to other bacterial sequences. The topology of gene trees constructed using several different methods are all consistent with the hypothesis of lateral gene transfer andnot ancient gene duplication. Furthermore, an estimate of a molecular clock forPgi dates the divergence of theE. coli andH. influenzae sequences from the animal sequences to between 470 and 650 million years ago, well after other estimates of the divergence between eukaryotes and bacteria. This study provides the most convincing evidence to date of the transkingdom transfer of a nuclear gene.