Your search keyword '"Aldrich, P. R"' showing total 2 results

1. Hybridization network for the system of woody plant gene pools in the United States.

Author

Aldrich, P. R, Horsley, R. K, and Turcic, S. M

Subjects

PLANT genes, WOODY plants, SPECIES hybridization, INTROGRESSION (Genetics), PLANT species, WHITE oak, NUMBERS of species

Abstract

Hybridization generates similarities among gene pools. This structure can be visualized and analyzed at the systems level using networks. Here we construct a network of the 315 woody plant species native or naturalized in the United States using data compiled by the Forest Service of the US Department of Agriculture (USFS). Each species is represented by a node in the network whose size is proportional to a recent census for live stems in the continental United States. Each of the 416 links between node pairs represents evidence for hybridization compiled from the USFS manual Silvics of North America. The total network resolved into 100 separate connected components or clusters (mean size, 3.15 species), with 44% of species linked to at least one other. Betula had the largest component (18 species) following by the separate Quercus clusters (17 red oaks and 16 white oaks); Q. velutina was the most genetically connected woody plant in the continental US. The number of species held together per component (i.e. size) scaled as a power-law albeit a slightly truncated one. The truncation suggests there are fewer than expected hybridizing species within the large woody genera of plants in the US. [ABSTRACT FROM AUTHOR]

Published

2012

2. Genetic Structure Inside a Declining Red Oak Community in Old-Growth Forest.

Author

Aldrich, P. R., Glaubitz, J. C., Parker, G. R., Rhodes Jr., O. E., Michler, C. H., and Burke, John

Subjects

RED oak, OAK, PLANT genetics, MICROSATELLITE repeats, NUCLEOTIDE sequence

Abstract

Problems with oak regeneration have been documented in the last 50 years at numerous sites in the Midwestern United States. We applied nuclear microsatellites to examine the demographic and fine-scale spatial genetic structure of red oaks in two old-growth stands in Indiana. Oaks in one stand have declined in numbers over the past several decades whereas oaks in the other, smaller stand have increased. Large amounts of genetic variation were maintained within stands, and there was slight but significant differentiation among stands. There was significant but weak isolation by distance genetic structure within the large stand, likely reflecting family structure. No significant differences exist in allele frequencies or in levels of genetic diversity between cohorts that remain well represented within each stand, even between medium-sized adults and those antedating European settlement of the area. However, a virtual absence of smaller size classes in the forest interior of the large stand represents the early stages of a genetic bottleneck in what had been the core habitat of this stand. Whether future generations of this old-growth stand will retain the present genetic character depends on the oaks regenerating at the forest margins, absent any major changes in disturbance regimes. Similar demographic and genetic dynamics are likely occurring in a large number of remnant oak forests across the Midwest. [ABSTRACT FROM AUTHOR]

Published

2005