In-cell NMR in mammalian cells: part 3.

Irrespective of how isotope-labeled proteins are delivered into mammalian cells, laboratory routines are needed to assess the quality of the resulting in-cell NMR samples. These include methods to evaluate overall cell viability, protein transduction efficiency, intracellular protein concentration, localization, and stability. In addition, quality control experiments to assess protein leakage from manipulated cells are of particular importance for in-cell NMR experiments.

In-cell NMR in mammalian cells: part 2.

Delivery of isotope-labeled IDPs into mammalian cells for the purpose of generating suitable in-cell NMR samples can also be facilitated by action of pore-forming bacterial toxins. In the course of this procedure, mammalian cell membranes are permeated for short periods of time in order to enable the influx of exogenous proteins via a concentration gradient between the outside and the inside of the targeted "host" cells. In contrast to CPP-mediated IDP uptake, toxins offer the advantage that cellular protein transduction does not rely on active biological processes like endocytosis, but on simple passive diffusion.

In-cell NMR in mammalian cells: part 1.

Many mammalian IDPs exert important biological functions in key cellular processes and often in highly specialized subsets of cells. For these reasons, tools to characterize the structural and functional characteristics of IDPs inside mammalian cells are of particular interest. Moving from bacterial and amphibian in-cell NMR experiments to mammalian systems offers the unique opportunity to advance our knowledge about general IDP properties in native cellular environments.

Timing constraints of in vivo gag mutations during primary HIV-1 subtype C infection.

Background: Aiming to answer the broad question "When does mutation occur?" this study examined the time of appearance, dominance, and completeness of in vivo Gag mutations in primary HIV-1 subtype C infection.

Methods: A primary HIV-1C infection cohort comprised of 8 acutely and 34 recently infected subjects were followed frequently up to 500 days post-seroconversion (p/s). Gag mutations were analyzed by employing single-genome amplification and direct sequencing.

Evolution of proviral gp120 over the first year of HIV-1 subtype C infection.

The evolution of proviral gp120 during the first year after seroconversion in HIV-1 subtype C infection was addressed in a case series of eight subjects. Multiple viral variants were found in two out of eight cases. Slow rate of viral RNA decline and high early viral RNA set point were associated with a higher level of proviral diversity from 0 to 200 days after seroconversion.

Recent advances in cancer research: mouse models of tumorigenesis.

Over the past 20 years, cancer research has gained major insights into the complexity of tumor development, in particular into the molecular mechanisms that underlie the progressive transformation of normal cells into highly malignant derivatives. It is estimated that the transformation of a normal cell to a malignant tumor cell is dependent upon a small number of genetic alterations, estimated to be within the range of four to seven rate-limiting events. Critical events in the evolution of neoplastic disease include the loss of proliferative control, the failure to undergo programmed cell death (apoptosis), the onset of neoangiogenesis, tissue remodeling, invasion of tumor cells into surrounding tissue and, finally, metastatic dissemination of tumor cells to distant organs.

Ras and TGF[beta] cooperatively regulate epithelial cell plasticity and metastasis: dissection of Ras signaling pathways.

Multistep carcinogenesis involves more than six discrete events also important in normal development and cell behavior. Of these, local invasion and metastasis cause most cancer deaths but are the least well understood molecularly. We employed a combined in vitro/in vivo carcinogenesis model, that is, polarized Ha-Ras-transformed mammary epithelial cells (EpRas), to dissect the role of Ras downstream signaling pathways in epithelial cell plasticity, tumorigenesis, and metastasis.