Developmental Changes in Genome Replication Progression in Pluripotent versus Differentiated Human Cells.

DNA replication is a fundamental process ensuring the maintenance of the genome each time cells divide. This is particularly relevant early in development when cells divide profusely, later giving rise to entire organs. Here, we analyze and compare the genome replication progression in human embryonic stem cells, induced pluripotent stem cells, and differentiated cells. Using single-cell microscopic approaches, we map the spatio-temporal genome replication as a function of chromatin marks/compaction level. Furthermore, we mapped the replication timing of subchromosomal tandem repeat regions and interspersed repeat sequence elements. Albeit the majority of these genomic repeats did not change their replication timing from pluripotent to differentiated cells, we found developmental changes in the replication timing of rDNA repeats. Comparing single-cell super-resolution microscopic data with data from genome-wide sequencing approaches showed comparable numbers of replicons and large overlap in origins numbers and genomic location among developmental states with a generally higher origin variability in pluripotent cells. Using ratiometric analysis of incorporated nucleotides normalized per replisome in single cells, we uncovered differences in fork speed throughout the S phase in pluripotent cells but not in somatic cells. Altogether, our data define similarities and differences on the replication program and characteristics in human cells at different developmental states.

Analysis of Cell Cycle and DNA Compaction Dependent Subnuclear Distribution of Histone Marks.

In eukaryotes, the organization of DNA wrapped around histones regulates DNA-dependent processes. Changes in epigenetic modifications modulate the compaction of DNA into chromatin and, thus, regulate DNA metabolism in time and space. Hence, to catalog the spatiotemporal epigenetic information and its relation to the dynamic nuclear landscape is of paramount importance. Here, we present a method, based on FiJi and the statistical image analysis tool nucim(R), to classify in 3D the nuclear DNA compaction in single interphase cells. We, furthermore, mapped the distribution of (epi)genetic marks and nuclear proteins/processes to the compaction classes along with their dynamics over the cell cycle. These techniques allow to catalog and quantify the dynamic changes in the epigenome in space and time and in single cells.

Design and development of thermionic emission microscope for the characterization of multi-beam cathode.

Thermionic emission microscope (THEM) is an important analytical research tool to study spatial emission distribution of a thermionic cathode. The criticality of its design and development stems from the need to characterize the inhomogeneous emission nature of the impregnated cathode surface. In this paper the design of lens and deflection plates for studying multi-beam cathode (MBC) is presented. To understand the electron optical performance of THEM, simulations were carried out using the simulation tools 2D-TRAK and Omni TRAK. These results were further validated using another software tool CST Particle Studio. The influence of various parameters of MBC such as protrusion, diameter of button and inter-button spacing have been studied.

TRPA1 is selected as a semi-conserved channel during vertebrate evolution due to its involvement in spermatogenesis.

TRPA1 is a non-selective cation channel originated in invertebrates. The genomic locus containing TRPA1 gene remains highly conserved and retained in all vertebrates. TRPA1 gene is evolutionarily selected, yet maintained as a highly diverged protein. Throughout the vertebrate evolution, the extracellular loops of TRPA1 become most diverged indicating that TRPA1 may be involved in detecting large spectrum and uncertain stimulus which is critical for adaptive benefit. We tested the expression of TRPA1 in mature sperm from different vertebrates. This is the first report demonstrating that TRPA1 is expressed endogenously in mature spermatozoa of multiple species representing entire vertebrate phyla. However, its specific localization within sperm remains species-specific. Accordingly, we report that in rodents TRPA1 expression correlates with different stages of spermatogenesis. We propose that presence of endogenous TRPA1 in testes and in mature sperm provides reproductive benefit.