p97, an abundant hexameric ATPase of the AAA family, is involved in homotypic membrane fusion. It is thought to disassemble SNARE complexes formed during the process of membrane fusion. Here, we report two structures: a crystal structure of the N-terminal and D1 ATPase domains of murine p97 at 2.9 A resolution, and a cryoelectron microscopy structure of full-length rat p97 at 18 A resolution. Together, these structures show that the D1 and D2 hexamers pack in a tail-to-tail arrangement, and that the N domain is flexible. A comparison with NSF D2 (ATP complex) reveals possible conformational changes induced by ATP hydrolysis. Given the D1 and D2 packing arrangement, we propose a ratchet mechanism for p97 during its ATP hydrolysis cycle.
PML is a component of a multiprotein complex, termed nuclear bodies, and the PML protein was originally discovered in patients suering from acute promyelocytic leukaemia (APL). APL is associated with a reciprocal chromosomal translocation of chromosomes 15 and 17, which results in a fusion protein comprising PML and the retinoic acid receptor a. The PML genomic locus is approximately 35 kb and is subdivided into nine exons. A large number of alternative spliced transcripts are synthesized from the PML gene, resulting in a variety of PML proteins ranging in molecular weight from 48 ± 97 kDa. In this review we summarize the data on the known PML isoforms and splice variants and present a new unifying nomenclature. Although, the function/s of the PML variants are unclear, all PML isoforms contain an identical N-terminal region, suggesting that these sequences are indispensable for function, but dier in their C-terminal sequences. The N-terminal region harbours a RING-®nger, two B-boxes and a predicted a-helical Coiled-Coil domain, that together form the RBCC/TRIM motif found in a large family of proteins. In PML this motif is essential for PML nuclear body formation in vivo and PML-homo and hetero interactions conferring growth suppressor, apoptotic and antiviral activities. In APL oligomerization mediated by the RBCC/TRIM motif is essential for the transformation potential of the PML-RARa fusion protein. Oncogene (2001) 20, 7223 ± 7233.
Promyelocytic leukemia (PML) is the organizer of nuclear matrix domains, PML nuclear bodies (NBs), with a proposed role in apoptosis control. In acute promyelocytic leukemia, PML/retinoic acid receptor (RAR) α expression disrupts NBs, but therapies such as retinoic acid or arsenic trioxide (As2O3) restore them. PML is conjugated by the ubiquitin-related peptide SUMO-1, a process enhanced by As2O3 and proposed to target PML to the nuclear matrix. We demonstrate that As2O3 triggers the proteasome-dependent degradation of PML and PML/RARα and that this process requires a specific sumolation site in PML, K160. PML sumolation is dispensable for its As2O3-induced matrix targeting and formation of primary nuclear aggregates, but is required for the formation of secondary shell-like NBs. Interestingly, only these mature NBs harbor 11S proteasome components, which are further recruited upon As2O3 exposure. Proteasome recruitment by sumolated PML only likely accounts for the failure of PML-K160R to be degraded. Therefore, studying the basis of As2O3-induced PML/RARα degradation we show that PML sumolation directly or indirectly promotes its catabolism, suggesting that mature NBs could be sites of intranuclear proteolysis and opening new insights into NB alterations found in viral infections or transformation.
The structure of the major human apurinic/ apyrimidinic endonuclease (HAP1) has been solved at 2.2 Å resolution. The enzyme consists of two symmetrically related domains of similar topology and has significant structural similarity to both bovine DNase I and its Escherichia coli homologue exonuclease III (EXOIII). A structural comparison of these enzymes reveals three loop regions specific to HAP1 and EXOIII. These loop regions apparently act in DNA abasic site (AP) recognition and cleavage since DNase I, which lacks these loops, correspondingly lacks AP site specificity. The HAP1 structure furthermore suggests a mechanism for AP site binding which involves the recognition of the deoxyribose moiety in an extrahelical conformation, rather than a 'flipped-out' base opposite the AP site.
Co-culture techniques find myriad applications in biology for studying natural or synthetic interactions between cell populations. Such techniques are of great importance in synthetic biology, as multi-species cell consortia and other natural or synthetic ecology systems are widely seen to hold enormous potential for foundational research as well as novel industrial, medical and environmental applications with many proof-of-principle studies in recent years. What is needed for co-cultures to fulfil their potential? Cell-cell interactions in cocultures are strongly influenced by the extracellular environment, which is determined by the experimental set-up, which therefore needs to be given careful consideration. An overview of existing experimental and theoretical co-culture set-ups in synthetic biology and adjacent fields is given here, and challenges and opportunities involved in such experiments are discussed. Greater focus on foundational technology developments for co-cultures is needed for many synthetic biology systems to realize their potential in both applications and answering biological questions.
Ubiquitination targets proteins for degradation and is a potent regulator of cellular protein function. Recent results implicate the RING finger domain in specific ubiquitination events; it is possible that all RING proteins act as E3 ubiquitin protein ligases, with implications for a variety of biological areas.
High-resolution crystal structures of editing complexes of both duplex and single-stranded DNA bound to Escherichia coli DNA polymerase I large fragment (Klenow fragment) show four nucleotides of single-stranded DNA bound to the 3'-5' exonuclease active site and extending toward the polymerase active site. Melting ofthe duplex DNA by the protein is stabilized by hydophobic interactions between Phe473, Leu-361, and His-666 and the last three bases at the 3' terminus. Two divalent metal ions interacting with the phosphodiester to be hydrolyzed are proposed to catalyze the exonuclease reaction by a mechanism that may be related to mechanisms of other enzymes that catalyze phospho-group transfer including RNA enzymes. We suggest that the editing active site competes with the polymerase active site some 30 A away for the newly formed 3' terminus. Since a 3' terminal mismatched base pair favors the melting of duplex DNA, its binding and excision at the editing exonuclease site that binds single-stranded DNA is enhanced.The large proteolytic fragment (Klenow fragment) of Escherichia coli DNA polymerase I utilizes an editing 3'-5' exonuclease activity (1) to reduce the misincorporation of erroneous nucleotides by about 10-fold (2) at an active site that is some 30 A away from the polymerase site of misincorporation (3). How might this be accomplished? The crystal structure of the Klenow fragment shows that it is folded into two domains (3). Various experiments (reviewed in ref. 4) establish that the domain to which the dNMP binds in the crystal catalyzes the 3'-5' econuclease activity, whereas the larger C-terminal domain contains the active site for the polymerase reaction. Mutant proteins that contain amino acid changes in the dNMP binding site have been made by directed mutagenesis; they are devoid of exonuclease activity but retain full polymerase activity (5). Furthermore, the DNA encoding the C-terminal domain has been cloned, and the product has been expressed, isolated, and shown to possess significant DNA polymerase activity with no measurable 3'-5' exonuclease activity (6). The observation (3) that these two active sites are -25-30 A apart poses the interesting question of how they work together to achieve high-fidelity synthesis of DNA.The C-terminal domain contains a cleft that is large enough to accommodate the double-stranded B-DNA product of DNA synthesis (3). The approximate position of the 3' terminus of the primer strand has been derived from the cross-linking of 8-azido-dATP to Tyr-776, footprinting of Klenow fragment on DNA (7), and the position of sitedirected mutants that alter polymerase activity but not exonuclease activity (A. Polesky and C. Joyce, personal communication). This model of DNA at the polymerase active site places about 8 base pairs (bp) of duplex product DNA in the cleft.A more detailed understanding of the structural basis ofthe polymerase and exonuclease activities requires the separate determination of the crystal structures of suitable DNAs complexed with each of these ...
Site-directed mutagenesis of the large fragment of DNA polymerase I (Klenow fragment) yielded two mutant proteins lacking 3',5'-exonuclease activity but having normal polymerase activity. Crystallographic analysis of the mutant proteins showed that neither had any alteration in protein structure other than the expected changes at the mutation sites. These results confirmed the presumed location of the exonuclease active site on the small domain of Klenow fragment and its physical separation from the polymerase active site. An anomalous scattering difference Fourier of a complex of the wild-type enzyme with divalent manganese ion and deoxythymidine monophosphate showed that the exonuclease active site has binding sites for two divalent metal ions. The properties of the mutant proteins suggest that one metal ion plays a role in substrate binding while the other is involved in catalysis of the exonuclease reaction.
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