Spatiotemporal response of living cell structures in Dictyostelium discoideum with semiconductor quantum dots.

The ability to monitor the spatial and temporal organization of molecules such as biopolymers within a cell is essential to enable the ability to understand the complexity and dynamics existing in biological processes. However, many limitations currently exist in specifically labeling proteins in living cells. In our study, we incorporate nanometer-sized semiconductor quantum dots (QDs) into living cells for spatiotemporal protein imaging of actin polymers in Dictyostelium discoideum without the necessity of using complicating transmembrane transport approaches. We first demonstrate cytoplasmic distribution of QDs within these living amoebae cells and then show molecular targeting through actin filament labeling. Also, we have developed a microfluidic system to control and visualize the spatiotemporal response of the cellular environment during cell motility, which allows us to demonstrate specific localization control of the QD-protein complexes in living cells. This study provides a valuable tool for the specific targeting and analysis of proteins within Dictyostelium without the encumbrance of transmembrane assisted methods, which has implication in fields including polymer physics, material science, engineering, and biology.

Multiple start codons and phosphorylation result in discrete Rad52 protein species.

The sequence of the Saccharomyces cerevisiae RAD52 gene contains five potential translation start sites and protein-blot analysis typically detects multiple Rad52 species with different electrophoretic mobilities. Here we define the gene products encoded by RAD52. We show that the multiple Rad52 protein species are due to promiscuous choice of start codons as well as post-translational modification. Specifically, Rad52 is phosphorylated both in a cell cycle-independent and in a cell cycle-dependent manner. Furthermore, phosphorylation is dependent on the presence of the Rad52 C terminus, but not dependent on its interaction with Rad51. We also show that the Rad52 protein can be translated from the last three start sites and expression from any one of them is sufficient for spontaneous recombination and the repair of gamma-ray-induced double-strand breaks.

Cell cycle-regulated centers of DNA double-strand break repair.

In eukaryotes, homologous recombination is an important pathway for the repair of DNA double-strand breaks. We have studied this process in living cells in the yeast Saccharomyces cerevisiae using Rad52 as a cell biological marker. In response to DNA damage, Rad52 redistributes itself and forms foci specifically during S phase. We have shown previously that Rad52 foci are centers of DNA repair where multiple DNA double-strand breaks colocalize. Here we report a correlation between the timing of Rad52 focus formation and modification of the Rad52 protein. In addition, we show that the two ends of a double-strand break are held tightly together in the majority of cells. Interestingly, in a small but significant fraction of the S phase cells, the two ends of a break separate suggesting that mechanisms exist to reassociate and align these ends for proper DNA repair.

Phylogenetics of worldwide human populations as determined by polymorphic Alu insertions.

Alu elements, the largest family of interspersed repeats, mobilize throughout the genomes of primates by retroposition. Alu are present in humans in an excess of 500 000 copies per haploid genome. Since some of the insertion alleles have not reached fixation, they remain polymorphic and can be used as biallelic DNA marker systems in investigations of human evolution. In this study, six polymorphic Alu insertional (PAI) loci were used as genetic markers. These markers are thought to be selectively neutral. The presence of these six PAIs was determined by a polymerase chain reaction (PCR)-based assay in 1646 individuals from 47 populations from around the world. Examination of the populations by plotting the first and second principal components, shows the expected segregation of populations according to geographical vicinity and established ethnic affinities. Centroid analysis demonstrated that sub-Sahara populations have experienced higher than average gene flow and/or represent larger populations as compared to groups in other parts of the globe and especially to known inbreed populations. This is consistent with greater heterogeneity and diversity expected of source groups. In addition, maximum likelihood (ML) analyses were performed with these 47 populations and a hypothetical ancestral group lacking the insertion in all six loci. Analysis of our data supports the Out of Africa hypothesis. African populations and admixed groups of African descent formed a single monophyletic group with a basal placement on the tree, which grouped closest to the hypothetical ancestor.