Unique residues involved in activation of the multitasking protease/chaperone HtrA from Chlamydia trachomatis

DegP, a member of the HtrA family of proteins, conducts critical bacterial protein quality control by both chaperone and proteolysis activities. The regulatory mechanisms controlling these two distinct activities, however, are unknown. DegP activation is known to involve a unique mechanism of allosteric binding, conformational changes and oligomer formation. We have uncovered a novel role for the residues at the PDZ1:protease interface in oligomer formation specifically for chaperone substrates of Chlamydia trachomatis HtrA (DegP homolog). We have demonstrated that CtHtrA proteolysis could be activated by allosteric binding and oligomer formation. The PDZ1 activator cleft was required for the activation and oligomer formation. However, unique to CtHtrA was the critical role for residues at the PDZ1:protease interface in oligomer formation when the activator was an in vitro chaperone substrate. Furthermore, a potential in vivo chaperone substrate, the major outer membrane protein (MOMP) from Chlamydia, was able to activate CtHtrA and induce oligomer formation. Therefore, we have revealed novel residues involved in the activation of CtHtrA which are likely to have important in vivo implications for outer membrane protein assembly.     

The uses of carcinogen-DNA adduct measurement in establishing mechanisms of mutagenesis and in chemoprevention

DNA adducts generated by carcinogenic chemicals reflects human exposure and DNA adducts are related to tumor formation. Most chemical carcinogens require activation to reactive intermediates that bind to nucleophilic centers in proteins and nucleic acids thereby forming covalent adducts. Also, many of the chemicals considered carcinogenic for humans form covalent DNA adducts. Therefore, such DNA damage is generally considered to be causative and linked to tumor formation. In this article we have summarized the work done for many years on the role of DNA adduct formation as an indicator of their carcinogenicity. We have also addressed the important role for measurement of DNA adducts in studies with potential chemopreventive agents for which it is central to have a marker that can be measured more rapidly than changes in cancer incidence.     

Unraveling the role of myosin in forming autophagosomes

Macroautophagy (hereafter autophagy) is a membrane-mediated catabolic process that occurs in response to a variety of intra- and extra-cellular stresses. It is characterized by the formation of specialized double-membrane vesicles, autophagosomes, which engulf organelles and long-lived proteins, and in turn fuse with lysosomes for degradation and recycling. How autophagosomes emerge is still unclear. The Atg1 kinase plays a crucial role in the induction of autophagosome formation. While several Atg (autophagy-related) proteins have been associated with, and have been found to regulate, Atg1 kinase activity, the downstream targets of Atg1 that trigger autophagy remain unknown. Our recent studies have identified a myosin light chain kinase (MLCK)-like kinase as the Atg1 kinase effector that induces the activation of myosin II, and have found it to be required for autophagosome formation during nutrient deprivation. We further demonstrated that Atg1-mediated myosin II activation is crucial for the movement of the Atg9 transmembrane protein between the Golgi and the forming autophagosome, which provides a membrane source for the formation of autophagosomes during starvation.     

Unraveling the role of myosin in forming autophagosomes

Macroautophagy (hereafter autophagy) is a membrane-mediated catabolic process that occurs in response to a variety of intra- and extra-cellular stresses. It is characterized by the formation of specialized double-membrane vesicles, autophagosomes, which engulf organelles and long-lived proteins, and in turn fuse with lysosomes for degradation and recycling. How autophagosomes emerge is still unclear. The Atg1 kinase plays a crucial role in the induction of autophagosome formation. While several Atg (autophagy-related) proteins have been associated with, and have been found to regulate, Atg1 kinase activity, the downstream targets of Atg1 that trigger autophagy remain unknown. Our recent studies have identified a myosin light chain kinase (MLCK)-like kinase as the Atg1 kinase effector that induces the activation of myosin II, and have found it to be required for autophagosome formation during nutrient deprivation. We further demonstrated that Atg1-mediated myosin II activation is crucial for the movement of the Atg9 transmembrane protein between the Golgi and the forming autophagosome, which provides a membrane source for the formation of autophagosomes during starvation.     

Early pattern formation in the developing Drosophila eye

The formation of complex cellular arrays from unpatterned epithelia is a widespread developmental phenomenon. Insights into the mechanisms regulating this transformation have come from studying the development of the Drosophila compound eye. Pattern formation in the eye primordium is a highly ordered process in which the onset of differentiation is coordinated with synchronization of cell cycle progression. Recent studies have identified a number of genes that are required for early patterning events, and provide a link between the regulation of proliferation and pattern formation.     

Tunneling nanotubes: A possible highway in the spreading of tau and other prion-like proteins in neurodegenerative diseases

The mechanisms of intercellular spreading of amyloidogenic proteins involved in neurodegenerative diseases have yet to be fully elucidated. While secretion has been implicated in the transfer of many proteins, including prions and α-synuclein, tunneling nanotubes (TNTs) have also been demonstrated for prions and mutant Huntingtin. Here, we provide further evidence that Tau aggregates, which have been demonstrated to predominantly be transferred via secretion, can also be found in TNTs. Additionally, cells that have taken up Tau have increased TNT formation. Coupled with previous evidence that other amyloidogenic aggregates also induce TNT formation we propose that misfolded protein aggregates can, through a common mechanism, promote the formation of TNTs and thereby their own intercellular transfer, contributing to the propagation of pathology.     

Diketopiperazine-mediated peptide formation in aqueous solution

Though diketopiperazines (DKP) are formed in most experiments concerning the prebiotic peptide formation, the molecules have not been paid attention in the studies of chemical evolution. We have found that triglycine, tetraglycine or pentaglycine are formed in aqueous solution of glycine anhydride (DKP) and glycine, diglycine or triglycine, respectively. A reaction of alanine with DKP resulted in the formation of glycylglycylalanine under the same conditions. These results indicate that the formation of the peptide bonds proceeds through the nucleophilic attack of an amino group of the amino acids or the oligoglycines on the DKP accompanied by the ring-opening.The formation of glycine anhydride, di-, tri- and tetraglycine was also observed in a mixed aqueous solution of urea and glycine in an open system to allow the evaporation of ammonia. A probable pathway is proposed for prebiotic peptide formation through diketopiperazine on the primitive Earth.     

Cell migration and invasion in human disease: the Tks adaptor proteins

Cell invasion plays a central role in a wide variety of biological phenomena and is the cause of tumour growth and metastasis. Understanding the biochemical mechanisms that control cell invasion is one of the major goals of our laboratory. Podosomes and invadopodia are specialized cellular structures present in cells with physiological or pathological invasive behaviours. These transient structures are localized at the ventral cell surface, contain an array of different proteins and facilitate cell-substrate adhesion, as well as the local proteolytic activity necessary for extracellular matrix remodelling and subsequent cellular invasion. We have shown previously that the adaptor proteins and Src substrates Tks4 and Tks5 are required for podosome and invadopodia formation, for cancer cell invasion in vitro, and for tumour growth in vivo. We have also defined a role for the Tks-mediated generation of ROS (reactive oxygen species) in both podosome and invadopodia formation, and invasive behaviour. Tks4 and Tks5 are also required for proper embryonic development, probably because of their roles in cell migration. Finally, we recently implicated podosome formation as part of the synthetic phenotype of vascular smooth muscle cells. Inhibitors of podosome and invadopodia formation might have utility in the treatment of vascular diseases and cancer. We have therefore developed a high-content cell-based high-throughput screening assay that allows us to identify inhibitors and activators of podosome/invadopodia formation. We have used this assay to screen for small-molecule inhibitors and defined novel regulators of invadopodia formation. In the present paper, I review these recent findings.     

Seven-Base-Pair Inverted Repeats in DNA Form Stable Hairpins in Vivo in Saccharomyces Cerevisiae

Palindromic sequences in single-stranded DNA and RNA have the potential for intrastrand base pairing, resulting in formation of "hairpin" structures. We previously reported a genetic method for detecting such structures in vivo in the yeast Saccharomyces cerevisiae. Below, we describe evidence indicating that a 14-base-pair palindrome (7 bp per inverted repeat) is sufficient for formation of a hairpin in vivo.     

Unequal signal and coding joint formation in human V(D)J recombination.

Substrates for studying V(D)J recombination in human cells and two human pre-B-cell lines that have active V(D)J recombination activity are described. Using these substrates, we have been able to analyze the relative efficiency of signal joint and coding joint formation. Coding joint formation was five- to sixfold less efficient than signal joint formation in both cell lines. This imbalance between the two halves of the reaction was demonstrated on deletional substrates, where each joint is assayed individually. In both cell lines, the inversional reaction (which requires formation of both a signal and a coding joint) was more than 20-fold less efficient than signal joint formation alone. The signal and coding sequences are identical in all of these substrates. Hence, the basis for these differential reaction ratios appears to be that coding joint and signal joint formation are both inefficient and their combined effects are such that inversions (two-joint reactions) reflect the product of these inefficiencies. Physiologically, these results have two implications. First, they show how signal and coding joint formation efficiencies can affect the ratio of deletional to inversional products at endogenous loci. Second, the fact that not all signal and coding joints go to completion implies that the recombinase is generating numerous broken ends. Such unresolved ends may participate in pathologic chromosomal rearrangements even when the other half of the same reaction may have proceeded to resolution.     

The roles of RNA in the synthesis of protein

The crystal structures of ribosomes that have been obtained since 2000 have transformed our understanding of protein synthesis. In addition to proving that RNA is responsible for catalyzing peptide bond formation, these structures have provided important insights into the mechanistic details of how the ribosome functions. This review emphasizes what has been learned about the mechanism of peptide bond formation, the antibiotics that inhibit ribosome function, and the fidelity of decoding.     

Neuromuscular synaptogenesis in wild-type and mutant zebrafish

Genetic screens for synaptogenesis mutants have been performed in many organisms, but few if any have simultaneously screened for defects in pre- and postsynaptic specializations. Here, we report the results of a small-scale genetic screen, the first in vertebrates, for defects in synaptogenesis. Using zebrafish as a model system, we identified seven mutants that affect different aspects of neuromuscular synapse formation. Many of these mutant phenotypes have not been previously reported in zebrafish and are distinct from those described in other organisms. Characterization of mutant and wild-type zebrafish, from the time that motor axons first arrive at target muscles through adulthood, has provided the new information about the cellular events that occur during neuromuscular synaptogenesis. These include insights into the formation and dispersal of prepatterned AChR clusters, the relationship between motor axon elongation and synapse size, and the development of precise appositions between presynaptic clusters of synaptic vesicles in nerve terminals and postsynaptic receptor clusters. In addition, we show that the mechanisms underlying synapse formation within the myotomal muscle itself are largely independent of those that underlie synapse formation at myotendinous junctions and that the outgrowth of secondary motor axons requires at least one cue not necessary for the outgrowth of primary motor axons, while other cues are required for both. One-third of the mutants identified in this screen did not have impaired motility, suggesting that many genes involved in neuromuscular synaptogenesis were missed in large scale motility-based screens. Identification of the underlying genetic defects in these mutants will extend our understanding of the cellular and molecular mechanisms that underlie the formation and function of neuromuscular and other synapses.     

A wider role for polyamines in biofilm formation

Polyamines play an essential role in biofilm formation of diverse Gram-negative and Gram-positive bacteria. Biosynthetic pathways and transport systems for diverse polyamines have been identified as key components of bacterial biofilm formation.     

Vertebrate development: Et in Arkadia

The similarities in organiser formation in Xenopus and mouse embryos have remained elusive. Recent evidence suggests a common mechanism, in which an intracellular protein, Arkadia, is required for formation of the mouse organiser and potentiates the effects of the signalling protein Nodal.     

Insights into lipid raft structure and formation from experiments in model membranes

Rafts are sphingolipid/cholesterol-rich lipid domains believed to exist within certain eukaryotic cell membranes. Model membrane studies have been key to understanding the basic physical principles behind raft formation. Recent fluorescence quenching studies have demonstrated that tight packing between sterols and sphingolipids is the driving force for raft formation, and have begun to decipher the rules governing how different molecules interact with rafts.     

胎盘发生中的表观遗传学

胚外组织尤其是胎盘的正常发生对于维持哺乳动物胎儿在子宫中的发育和生长是必须的。胎盘发生是一个复杂的基因表达调控的过程,近年来的研究表明表观遗传在该过程中也起着重要作用。表观遗传调控在胎盘发生过程的几个主要事件中发挥作用,包括表观遗传对滋养层细胞分化和发育的调控、印记基因对胎盘发生和营养转运的调控、胎盘中的X染色体失活,以及胎盘表观遗传调控异常所导致的妊娠相关疾病。