Leonora Poljak

The RNase E of Escherichia coli is a membrane-binding protein.

RNase E is an essential endoribonuclease involved in RNA processing and mRNA degradation. The N‐terminal half of the protein encompasses the catalytic domain; the C‐terminal half is the scaffold for the assembly of the multienzyme RNA degradosome. Here we identify and characterize ‘segment‐A’, an element in the beginning of the non‐catalytic region of RNase E that is required for membrane binding. We demonstrate in vitro that an oligopeptide corresponding to segment‐A has the propensity to form an amphipathic α‐helix and that it avidly binds to protein‐free phospholipid vesicles. We demonstrate in vitro and in vivo that disruption of segment‐A in full‐length RNase E abolishes membrane binding. Taken together, our results show that segment‐A is necessary and sufficient for RNase E binding to membranes. Strains in which segment‐A has been disrupted grow slowly. Since in vitro experiments show that phospholipid binding does not affect the ribonuclease activity of RNase E, the slow‐growth phenotype might arise from a defect involving processes such as accessibility to substrates or interactions with other membrane‐bound machinery. This is the first report demonstrating that RNase E is a membrane‐binding protein and that its localization to the inner cytoplasmic membrane is important for normal cell growth.

The RNase E of Escherichia coli has at least two binding sites for DEAD-box RNA helicases: functional replacement of RhlB by RhlE.

The non‐catalytic region of Escherichia coli RNase E contains a protein scaffold that binds to the other components of the RNA degradosome. Alanine scanning yielded a mutation, R730A, that disrupts the interaction between RNase E and the DEAD‐box RNA helicase, RhlB. We show that three other DEAD‐box helicases, SrmB, RhlE and CsdA also bind to RNase E in vitro. Their binding differs from that of RhlB because it is not affected by the R730A mutation. Furthermore, the deletion of residues 791–843, which does not affect RhlB binding, disrupts the binding of SrmB, RhlE and CsdA. Therefore, RNase E has at least two RNA helicase binding sites. Reconstitution of a complex containing the protein scaffold of RNase E, PNPase and RhlE shows that RhlE can furnish an ATP‐dependent activity that facilitates the degradation of structured RNA by PNPase. Thus, RhlE can replace the function of RhlB in vitro. The results in the accompanying article show that CsdA can also replace RhlB in vitro. Thus, RhlB, RhlE and CsdA are interchangeable in in vitro RNA degradation assays.

Resolving the role of topoisomerase II in chromatin structure and function

The catalytic activities of topoisomerase II are responsible primarily for solving the complex topological problems that arise from cellular processes such as DNA replication, transcription and chromosome segregation; however, topoisomerase II may also play a crucial structural role in the chromosome scaffold. Cell-cycle-regulated phosphorylation might be the key to these diverse functions. Phosphorylation of topoisomerase II might trigger the enzymatic activities essential for mitosis and promote interactions with specialized DNA sequences and other protein components of the eukaryotic chromosome to ensure the proper establishment and maintenance of chromatin architecture and function.

Analysis of NCp7-dependent Activation of HIV-1 cDNA Integration and its Conservation Among Retroviral Nucleocapsid Proteins

HIV-1 nucleocapsid protein NCp7 is a small basic protein with two zinc fingers, found in the virion core where several hundred molecules coat the genomic RNA. NCp7 has nucleic acid chaperone properties that guide reverse transcriptase (RT) to synthesize the proviral DNA flanked by the long terminal repeats (LTR). In vitro, NCp7 can strongly activate magnesium-dependent LTR-DNA strand transfer by integrase (IN). Here we show that IN activation relies on both the basic residues and the zinc fingers of NCp7. NCp7 lacking the zinc fingers binds DNA but moderately stimulates strand transfer by IN. The NCp7 zinc-finger domain binds DNA poorly and does not efficiently stimulate IN activity. However, the NC zinc-finger domain can complement DNA binding to restore full activation of strand transfer by IN. We propose that the basic residues and the zinc fingers function together to stabilize IN at the LTR ends and promote the formation of a nucleoprotein complex competent for integration. We also show that these properties of HIV-1 NCp7 are remarkably conserved among nucleocapsid proteins of retrotransposon and retrovirus origins.

Membrane Recognition and Dynamics of the RNA Degradosome

RNase E, which is the central component of the multienzyme RNA degradosome, serves as a scaffold for interaction with other enzymes involved in mRNA degradation including the DEAD-box RNA helicase RhlB. Epifluorescence microscopy under live cell conditions shows that RNase E and RhlB are membrane associated, but neither protein forms cytoskeletal-like structures as reported earlier by Taghbalout and Rothfield. We show that association of RhlB with the membrane depends on a direct protein interaction with RNase E, which is anchored to the inner cytoplasmic membrane through an MTS (Membrane Targeting Sequence). Molecular dynamics simulations show that the MTS interacts with the phospholipid bilayer by forming a stabilized amphipathic α-helix with the helical axis oriented parallel to the plane of the bilayer and hydrophobic side chains buried deep in the acyl core of the membrane. Based on the molecular dynamics simulations, we propose that the MTS freely diffuses in the membrane by a novel mechanism in which a large number of weak contacts are rapidly broken and reformed. TIRFm (Total Internal Reflection microscopy) shows that RNase E in live cells rapidly diffuses over the entire inner membrane forming short-lived foci. Diffusion could be part of a scanning mechanism facilitating substrate recognition and cooperativity. Remarkably, RNase E foci disappear and the rate of RNase E diffusion increases with rifampicin treatment. Control experiments show that the effect of rifampicin is specific to RNase E and that the effect is not a secondary consequence of the shut off of E. coli transcription. We therefore interpret the effect of rifampicin as being due to the depletion of RNA substrates for degradation. We propose a model in which formation of foci and constraints on diffusion arise from the transient clustering of RNase E into cooperative degradation bodies.

Co-immunopurification of multiprotein complexes containing RNA-degrading enzymes.

Co-immunopurification is a classical technique in which antiserum raised against a specific protein is used to purify a multiprotein complex. We describe work from our laboratory in which co-immunopurification was used to characterize the RNA degradosome of Escherichia coli, a multiprotein complex involved in RNA processing and mRNA degradation. Polyclonal rabbit antibodies raised against either RNase E or PNPase, two RNA degrading enzymes in the RNA degradosome, were used in co-immunopurification experiments aimed at studying the assembly of the RNA degradosome and mapping protein-protein interactions within the complex. In E. coli, this method has been largely supplanted by approaches in which proteins are engineered to contain tags that interact with commercially available antibodies. Nevertheless, we believe that the method described here is valid for the study of bacteria in which the genetic engineering needed to introduce tagged proteins is difficult or nonexistent. As an example, we briefly discuss ongoing work in our laboratory on the characterization of RNase E in the psychrotolerant bacterium Pseudoalteromonas haloplanktis.

Chapter 10 Assaying DEAD‐box RNA Helicases and Their Role in mRNA Degradation in Escherichia coli

The DEAD-box RNA helicases are a ubiquitous family of enzymes involved in processes that include RNA splicing, ribosome biogenesis, and mRNA degradation. In general, these enzymes help to unwind short stretches of double-stranded RNA in processes that involve the remodeling of RNA structure or of ribonucleoprotein complexes. Here we describe work from our laboratory on the characterization of the RhlB of Escherichia coli, a DEAD-box RNA helicase that is part of a multienzyme complex known as the RNA degradosome. RhlB interacts physically and functionally with RNase E and polynucleotide phosphorylase (PNPase), two other components of the RNA degradosome. We describe enzyme assays that demonstrated that the interaction between RhlB and RNase E is necessary for the ATPase and RNA unwinding activities of RhlB. We also describe an mRNA degradation assay that showed that RhlB facilitates the degradation of structured mRNA by PNPase. These assays are discussed in the context of how they have contributed to our understanding of the function of RhlB in mRNA degradation.