Large-scale analysis of phosphorylation site occupancy in eukaryotic proteins

Many recent high throughput technologies have enabled large-scale discoveries of new phosphorylation sites and phosphoproteins. Although they have provided a number of insights into protein phosphorylation and the related processes, an inclusive analysis on the nature of phosphorylated sites in proteins is currently lacking. We have therefore analyzed the occurrence and occupancy of phosphorylated sites (~100,281) in a large set of eukaryotic proteins (~22,995). Phosphorylation probability was found to be much higher in both the termini of protein sequences and this is much pronounced in transmembrane proteins. A large proportion (51.3%) of occupied sites had a nearby phosphorylation within a distance of 10 amino acids; however, this proportion is very high compared to the expected one (16.9%). The distribution of phosphorylated sites in proteins showed a strong deviation from the expected maximum randomness. An analysis of phosphorylation motifs indicated that just 40 motifs and a much lower number of associated kinases might account for nearly 50% of the known phosphorylations in eukaryotic proteins. Our results provide a broad picture of the phosphorylation sites in eukaryotic proteins.     

Large-scale analysis of phosphorylation site occupancy in eukaryotic proteins

Many recent high throughput technologies have enabled large-scale discoveries of new phosphorylation sites and phosphoproteins. Although they have provided a number of insights into protein phosphorylation and the related processes, an inclusive analysis on the nature of phosphorylated sites in proteins is currently lacking. We have therefore analyzed the occurrence and occupancy of phosphorylated sites (~ 100,281) in a large set of eukaryotic proteins (~ 22,995). Phosphorylation probability was found to be much higher in both the termini of protein sequences and this is much pronounced in transmembrane proteins. A large proportion (51.3%) of occupied sites had a nearby phosphorylation within a distance of 10 amino acids; however, this proportion is very high compared to the expected one (16.9%). The distribution of phosphorylated sites in proteins showed a strong deviation from the expected maximum randomness. An analysis of phosphorylation motifs indicated that just 40 motifs and a much lower number of associated kinases might account for nearly 50% of the known phosphorylations in eukaryotic proteins. Our results provide a broad picture of the phosphorylation sites in eukaryotic proteins.     

Visualizing chromatin and chromosomes in living cells

The dynamic organization of eukaryotic genomes in cell nuclei recently came into the focus of research interest. The kinetics of genome dynamics can be addressed only by approaches involving live cell microscopy. Different methods are available to visualize chromatin, specific chromatin fractions, or individual chromosome territories within nuclei of living mammalian cells. Appropriate labeling procedures as well as cell chamber systems and important controls for live cell microscopy are described.     

My favourite molecule: Polyamines,chromatin structure and transcription

Nucleosomes are the basic elements of chromatin structure. Polyamines, such as spermine and spermidine, are small ubiquitous molecules absolutely required for cell growth. Photoaffinity polyamines bind to specific locations in nucleosomes and can change the helical twist of DNA in nucleosomes. Acetylation of polyamines reduces their affinity for DNA and nucleosomes, thus the helical twist of DNA in nucleosomes could be regulated by cells through acetylation. I suggest that histone and polyamine acetylation act synergistically to modulate chromatin structure. On naked DNA, the photoaffinity spermine bound preferentially to a specific ‘TATA’ sequence element, suggesting that polyamines may be involved in the unusual chromatin structure in this region. Further work is needed to test whether the specificities shown by photoaffinity polyamines are also shown by cellular polyamines; such experiments are now feasible.     

Rationalization of gene regulation by a eukaryotic transcription factor: calculation of regulatory region occupancy from predicted binding affinities

The antigen-binding fragments (Fab) of antibodies are powerful tools in clinical therapy, molecular diagnostics and basic research. However, their principal applications require pure recombinant molecules in large amounts, which are challenging to obtain. Severe limitations in yield, folding and functionality are commonly encountered in bacterial production of Fab fragments. Secretion into the oxidizing periplasm generally results in low yield, whereas expression in the reducing cytoplasmic environment produces unfolded or non-functional protein. We hypothesized that an impaired reducing environment of the cytoplasm would permit correctly folded, functional cytoplasmic expression of Fabs with high yield. We used the Escherichia coli strain FA113, which has no activity of both thioredoxin and glutathione reductase, and thus has an oxidizing cytoplasmic environment. With the newly constructed vector pFAB1 we tested the cytoplasmic expression of two Fab fragments, which recognize the integral membrane protein NhaA, a bacterial Na(+)/H(+) antiporter. These antibodies differ in terms of DNA sequence and stability. Both antibody fragments were produced to very high yields (10-30 mg/l from bacterial cultures at an A(600 nm)=1.2-1.3). This is a factor 50-250 times higher than any other reported over-expression strategy for Fab fragments and currently represents the highest production rate ever been reported for antibody Fab fragments in bacteria grown to similar cell densities. The fragments are fully functional and can be efficiently purified by His-tag chromatography. Expression of active Fab fragments in the bacterial cytoplasm unlocks the possibility of using antibody specific targeting in an intracellular environment. Such a capacity opens new perspectives for investigating metabolic and regulatory pathways in vivo and also provides a powerful selection system for functional genomics.     

Changes in chromatin structure and mobility in living cells at sites of DNA double-strand breaks

The repair of DNA double-strand breaks (DSBs) is facilitated by the phosphorylation of H2AX, which organizes DNA damage signaling and chromatin remodeling complexes in the vicinity of the lesion. The disruption of DNA integrity induces an alteration of chromatin architecture that has been proposed to activate the DNA damage transducing kinase ataxia telangiectasia mutated. However, little is known about the physical properties of damaged chromatin. In this study, we use a photoactivatable version of GFP-tagged histone H2B to examine the mobility and structure of chromatin containing DSBs in living cells. We find that chromatin containing DSBs exhibits limited mobility but undergoes an energy-dependent local expansion immediately after DNA damage. The localized expansion observed in real time corresponds to a 30-40% reduction in the density of chromatin fibers in the vicinity of DSBs, as measured by energy-filtering transmission electron microscopy. The observed opening of chromatin occurs independently of H2AX and ATM. We propose that localized adenosine triphosphate-dependent decondensation of chromatin at DSBs establishes an accessible subnuclear environment that facilitates DNA damage signaling and repair.