Mechanistic Dissection of the Cop9 Signalosome’s Deneddylation Activity on Cullin-RING Ligases

We set out to understand the precise mechanisms that regulate the activation and deactivation of Cullin-RING Ligases (CRLs). While a great deal of work has already gone into identifying the players involved in these pathways and the cellular consequences associated with the loss of each, the biochemical mechanisms regulating these steps have remained elusive. In this work we sought to gain a better understanding of the mechanisms behind these steps by teasing apart specific their biochemical reactions. By measuring the individual microscopic rate constants of the reactions we have shed light on both the proper sequence of events in the regulation of CRLs as well as how they are in fact controlled.

Prior to this work, it was believed that CSN deactivated CRLs by binding them and enzymatically removing the activating post-translation modification Nedd8. It was believed that CSN could not bind to CRLs while they were active due to the steric hindrance by the CRL substrates, and that they would remain bound to deneddylated CRLs as a sequestering agent until a new substrate could displace it. We now have some insight that substrates themselves cannot inhibit CSN very well, but that the active ubiquitination by an E2 enzyme precludes CSN binding and activity. When the substrate for a CRL becomes depleted, CSN then binds to the CRL in a low affinity, low activity conformation. This triggers a conformational change that pulls the autoinhibitory Ins-1 loop away from the active site in the catalytic subunit Csn5, resulting in a large increase in affinity and cleavage of the isopeptide bond between CRLs and Nedd8. Upon dissociation of Nedd8, CSN rapidly returns to the low affinity state and dissociates from the CRL, allowing it reenter its activation cycle.

Temporal and spacial control of RNA stability in the early embryo of Drosophila melanogaster

Early embryogenesis in metazoa is controlled by maternally synthesized products. Among these products, the mature egg is loaded with transcripts representing approximately two thirds of the genome. A subset of this maternal RNA pool is degraded prior to the transition to zygotic control of development. This transfer of control of development from maternal to zygotic products is referred to as the midblastula transition (or MBT). It is believed that the degradation of maternal transcripts is required to terminate maternal control of development and to allow zygotic control of development to begin. Until now this process of maternal transcript degradation and the subsequent timing of the MBT has been poorly understood. I have demonstrated that in the early embryo there are two independent RNA degradation pathways, either of which is sufficient for transcript elimination. However, only the concerted action of both pathways leads to elimination of transcripts with the correct timing, at the MBT. The first pathway is maternally encoded, is triggered by egg activation, and is targeted to specific classes of mRNAs through cis-acting elements in the 3' untranslated region (UTR}. The second pathway is activated 2 hr after fertilization and functions together with the maternal pathway to ensure that transcripts are degraded by the MBT. In addition, some transcripts fail to degrade at select subcellular locations adding an element of spatial control to RNA degradation. The spatial control of RNA degradation is achieved by protecting, or masking, transcripts from the degradation machinery. The RNA degradation and protection events are regulated by distinct cis-elements in the 3' untranslated region (UTR). These results provide the first systematic dissection of this highly conserved process in development and demonstrate that RNA degradation is a novel mechanism used for both temporal and spatial control of development.