Irene Lee

Multitasking in the mitochondrion by the ATP-dependent Lon protease ☆

The AAA(+) Lon protease is a soluble single-ringed homo-oligomer, which represents the most streamlined operational unit mediating ATP-dependent proteolysis. Despite its simplicity, the architecture of Lon proteases exhibits a species-specific diversity. Homology modeling provides insights into the structural features that distinguish bacterial and human Lon proteases as hexameric complexes from yeast Lon, which is uniquely heptameric. The best-understood functions of mitochondrial Lon are linked to maintaining proteostasis under normal metabolic conditions, and preventing proteotoxicity during environmental and cellular stress. An intriguing property of human Lon is its specific binding to G-quadruplex DNA, and its association with the mitochondrial genome in cultured cells. A fraction of Lon preferentially binds to the control region of mitochondrial DNA where transcription and replication are initiated. Here, we present an overview of the diverse functions of mitochondrial Lon, as well as speculative perspectives on its role in protein and mtDNA quality control.

Functional mechanics of the ATP-dependent Lon protease- lessons from endogenous protein and synthetic peptide substrates

Lon, also known as the protease La, is a homo-oligomeric ATP-dependent protease, which is highly conserved in archaea, eubacteria and eukaryotic mitochondria and peroxisomes. Since its discovery, studies have shown that Lon activity is essential for cellular homeostasis, mediating protein quality control and metabolic regulation. This article highlights the discoveries made over the past decade demonstrating that Lon selectively degrades abnormal as well as certain regulatory proteins and thus plays significant roles in maintaining bacterial and mitochondrial function and integrity. In addition, Lon is required in certain pathogenic bacteria, for rendering pathogenicity and host infectivity. Recent research endeavors have been directed toward elucidating the reaction mechanism of the Lon protease by different biochemical and structural biological techniques. In this mini-review, the authors survey the diverse biological roles of Lon, and also place special emphasis on recent findings that clarify the mechanistic aspects of the Lon reaction cycle.

The ATP-dependent Lon protease of Mus musculus is a DNA-binding protein that is functionally conserved between yeast and mammals.

The ATP-dependent Lon protease is a multi-functional enzyme that is conserved from archae to mammalian mitochondria, which not only degrades protein substrates but also binds DNA. As a starting point toward understanding Lon function in development, the mouse Lon cDNA was cloned and the encoded protein was characterized in cultured mammalian cells, in yeast and in vitro. Mouse Lon shows 87, 40 and 33% amino acid similarity with the human, yeast and bacterial homologs, respectively. Expression of a single mouse Lon transcript is detected in liver>heart>kidney>testis and is present during early embryonic development. Endogenous as well as transiently overexpressed mouse Lon co-localize with mitochondrial markers and have half-lives greater than 24 h as determined by pulse-chase studies. Enzymatically active mouse Lon that hydrolyses ATP and degrades protein and peptide substrates in an ATP-dependent manner also specifically binds to single-stranded but not to double-stranded DNA oligonucleotides. We propose that binding to TG-rich DNA sequences has been conserved between the mouse and human proteins. In addition, the evolutionary conservation of mitochondrial Lon function is demonstrated by the ability of mouse Lon to substitute for the yeast protein in vivo.

Catalytic antibodies: Perusing combinatorial libraries

Combinatorial libraries are a promising alternative for isolating catalytic antibodies produced by the immune system in response to the transition-state analog of a given reaction. Large, diverse panels of antibodies with high affinity for the transition-state analog can be isolated using screening or selection approaches. Furthermore, we have estimated that nucleotide sequences that bear close similarity to the sequence for a known catalytic antibody occur in combination at frequencies sufficient for their detection in such libraries.

Gold-containing indoles as anticancer agents that potentiate the cytotoxic effects of ionizing radiation.

This report describes the design and application of several distinct gold-containing indoles as anticancer agents. When used individually, all gold-bearing compounds display cytostatic effects against leukemia and adherent cancer cell lines. However, two gold-bearing indoles show unique behavior by increasing the cytotoxic effects of clinically relevant levels of ionizing radiation. Quantifying the amount of DNA damage demonstrates that each gold-indole enhances apoptosis by inhibiting DNA repair. Both Au(I)-indoles were tested for inhibitory effects against various cellular targets including thioredoxin reductase, a known target of several gold compounds, and various ATP-dependent kinases. While neither compound significantly inhibits the activity of thioreoxin reductase, both showed inhibitory effects against several kinases associated with cancer initiation and progression. The inhibition of these kinases provides a possible mechanism for the ability of these Au(I)-indoles to potentiate the cytotoxic effects of ionizing radiation. Clinical applications of combining Au(I)-indoles with ionizing radiation are discussed as a new strategy to achieve chemosensitization of cancer cells.

A revised strategy for cloning antibody gene fragments in bacteria.

The ability to clone and overexpress genes encoding mouse Fab (antigen-binding fragment) proteins in bacteria led to the development of a methodology which has the potential to replace traditional hybridoma technology [Huse et al., Science 246 (1989) 1275-1281]; however, several observations have suggested that clones with desirable chemical properties may be missed in immunoscreens of large combinatorial libraries due to low levels of functional Ab protein. To increase the efficiency of cloning and characterization of Ab gene fragments, we have reconsidered several features of the original cloning vehicles. These studies show that at the present time a unique expression system cannot adequately accommodate the requirements of plaque-lift immunoassays for clonal selection and biochemical assays for further characterization in vitro. A monocistronic arrangement of heavy- and light-chain-encoding genes using two lacP promoters produces sufficient amounts of functional Ab protein for clonal selection from phage lambda libraries and minimizes interference with the lytic cycle of recombinant vectors. In liquid culture, a strong coliphage promoter and a relatively abundant RNA polymerase can be used to produce quantities of Ab protein sufficient for further characterization in vitro. A rapid purification protocol obviates the need for fusing heavy-chain protein to a decapeptide sequence, an affinity-tail sequence which slows the folding and assembly of the Ig heterodimer. These results have been used to formulate a new strategy for cloning and characterization of Ab gene fragments in bacteria.

Quantifying the energetic contributions of desolvation and π-electron density during translesion DNA synthesis

This report examines the molecular mechanism by which high-fidelity DNA polymerases select nucleotides during the replication of an abasic site, a non-instructional DNA lesion. This was accomplished by synthesizing several unique 5-substituted indolyl 2′-deoxyribose triphosphates and defining their kinetic parameters for incorporation opposite an abasic site to interrogate the contributions of π-electron density and solvation energies. In general, the Kd, app values for hydrophobic non-natural nucleotides are ∼10-fold lower than those measured for isosteric hydrophilic analogs. In addition, kpol values for nucleotides that contain less π-electron densities are slower than isosteric analogs possessing higher degrees of π-electron density. The differences in kinetic parameters were used to quantify the energetic contributions of desolvation and π-electron density on nucleotide binding and polymerization rate constant. We demonstrate that analogs lacking hydrogen-bonding capabilities act as chain terminators of translesion DNA replication while analogs with hydrogen bonding functional groups are extended when paired opposite an abasic site. Collectively, the data indicate that the efficiency of nucleotide incorporation opposite an abasic site is controlled by energies associated with nucleobase desolvation and π-electron stacking interactions whereas elongation beyond the lesion is achieved through a combination of base-stacking and hydrogen-bonding interactions.

Non-Natural Nucleotides as Probes for the Mechanism and Fidelity of DNA Polymerases

DNA is a remarkable macromolecule that functions primarily as the carrier of the genetic information of organisms ranging from viruses to bacteria to eukaryotes. The ability of DNA polymerases to efficiently and accurately replicate genetic material represents one of the most fundamental yet complex biological processes found in nature. The central dogma of DNA polymerization is that the efficiency and fidelity of this biological process is dependent upon proper hydrogen-bonding interactions between an incoming nucleotide and its templating partner. However, the foundation of this dogma has been recently challenged by the demonstration that DNA polymerases can effectively and, in some cases, selectively incorporate non-natural nucleotides lacking classic hydrogen-bonding capabilities into DNA. In this review, we describe the results of several laboratories that have employed a variety of non-natural nucleotide analogs to decipher the molecular mechanism of DNA polymerization. The use of various non-natural nucleotides has lead to the development of several different models that can explain how efficient DNA synthesis can occur in the absence of hydrogen-bonding interactions. These models include the influence of steric fit and shape complementarity, hydrophobicity and solvation energies, base-stacking capabilities, and negative selection as alternatives to rules invoking simple recognition of hydrogen-bonding patterns. Discussions are also provided regarding how the kinetics of primer extension and exonuclease proofreading activities associated with high-fidelity DNA polymerases are influenced by the absence of hydrogen-bonding functional groups exhibited by non-natural nucleotides.

Replication of a Universal Nucleobase Provides Unique Insight into the Role of Entropy During DNA Polymerization and Pyrophosphorolysis

Most models accounting for the efficiency and fidelity of DNA polymerization invoke the use of either hydrogen bonding contacts or complementarity of shape and size between the formed base pair. This report evaluates these mechanisms by quantifying the ability of a high-fidelity DNA polymerase to replicate 5-nitroindole, a purine mimetic devoid of classic hydrogen bonding capabilities. 5-NITP acts as a universal nucleotide since it is incorporated opposite any of the four natural nucleobases with nearly equal efficiencies. Surprising, the polymerization reaction is not reciprocal as natural nucleotides are poorly incorporated opposite 5-nitroindole in the template strand. Incorporation opposite 5-nitroindole is more efficient using natural nucleotides containing various modifications that increase their base stacking potential. However, 5-substituted indolyl nucleotides that contain pi-electron and/or hydrophobic groups are incorporated opposite the non-natural nucleobase with the highest catalytic efficiencies. The collective data set indicate that replication of a non-natural nucleobase is driven by a combination of the hydrophobic nature and pi-electron surface area of the incoming nucleotide. In this mechanism, the overall hydrophobicity of the incoming nucleobase overcomes the lack of hydrogen bonding groups that are generally required for optimal DNA polymerization. However, the lack of hydrogen bonds between base pairs prevents primer extension. This final aspect is manifest by the appearance of unusually high pyrophosphorolysis activity by the T4 DNA polymerase that is only observed with the non-natural nucleobase in the template. These results highlight the importance of hydrogen bonding interactions during primer extension and pyrophosphorolysis.

Utilization of synthetic peptides to evaluate the importance of substrate interaction at the proteolytic site of Escherichia coli Lon protease

Lon, also known as protease La, is an ATP-dependent protease functioning to degrade many unstructured proteins. Currently, very little is known about the substrate determinants of Lon at the proteolytic site. Using synthetic peptides constituting different regions of the endogenous protein substrate lambdaN, we demonstrated that the proteolytic site of Escherichia coli Lon exhibits a certain level of localized sequence specificity. Using an alanine positional scanning approach, we discovered a set of discontinuous substrate determinants surrounding the scissile Lon cleavage site in a model peptide substrate, which function to influence the k(cat) of the peptidase activity of Lon. We further investigated the mode of peptide interaction with the proteolytically inactive Lon mutant S679A in the absence and presence of ADP or AMPPNP by 2-dimensional nuclear magnetic resonance spectroscopy, and discovered that the binding interaction between protein and peptide varies with the nucleotide bound to the enzyme. This observation is suggestive of a substrate translocation step, which likely limits the turnover of the proteolytic reaction. The contribution of the identified substrate determinants towards the kinetics of ATP-dependent degradation of lambdaN and truncated lambdaN mutants by Lon was also examined. Our results indicated that Lon likely recognizes numerous discontinuous substrate determinants throughout lambdaN to achieve substrate promiscuity.