Characterising the Binding Specificities of the Subunits Associated with the KMT2/Set1 Histone Lysine Methyltransferase

KMT2/Set1 is the catalytic subunit of the complex of proteins associated with Set1 (COMPASS) that is responsible for the methylation of lysine 4 of histone H3 (H3K4) in Saccharomyces cerevisiae. Whereas monomethylated H3K4 (H3K4me1) is found throughout the genome, di- (H3K4me2) and tri- (H3K4me3) methylated H3K4 are enriched at specific loci, which correlates with the promoter and 5′-ends of actively transcribed genes in the case of H3K4me3. The COMPASS subunits contain a number of domains that are conserved in homologous complexes in higher eukaryotes and are reported to interact with modified histones. However, the exact organization of these subunits and their role within the complex have not been elucidated. In this study we showed that: (1) subunits Swd1 and Swd3 form a stable heterodimer that dissociates upon binding to a modified H3K4me2 tail peptide, suggesting a regulatory role in COMPASS; (2) the affinity of the subunit Spp1 for modified histone H3 substrates is much higher than that of Swd1 and Swd3; (3) Spp1 has a preference for H3K4me2/3 methylation state; and (4) Spp1 contains a high-affinity DNA-binding domain in the previously uncharacterised C-terminal region. These data allow us to suggest a mechanism for the regulation of COMPASS activity at an actively transcribed gene.     

Systematic RNAi studies on the role of Sp/KLF factors in globin gene expression and erythroid differentiation

Sp/KLF family of factors regulates gene expression by binding to the CACCC/GC/GT boxes in the DNA through their highly conserved three zinc finger domains. To investigate the role of this family of factors in erythroid differentiation and globin gene expression, we first measured the expression levels of selected Sp/KLF factors in primary cells of fetal and adult stages of erythroid development. This quantitative analysis revealed that their expression levels vary significantly in cells of either stages of the erythroid development. Significant difference in their expression levels was observed between fetal and adult erythroid cells for some Sp/KLF factors. Functional studies using RNA interference revealed that the silencing of Sp1 and KLF8 resulted in elevated level of gamma globin expression in K562 cells. In addition, K562 cells become visibly red after Sp1 knockdown. Benzidine staining revealed significant hemoglobinization of these cells, indicating erythroid differentiation. Moreover, the expression of PU.1, ETS1 and Notch1 is significantly down-regulated in the cells that underwent erythroid differentiation following Sp1 knockdown. Overexpression of PU.1 or ETS1 efficiently blocked the erythroid differentiation caused by Sp1 knockdown in K562 cells. The expression of c-Kit, however, was significantly up-regulated. These data indicate that Sp1 may play an important role in erythroid differentiation.     

A proteasome assembly defect in rpn3 mutants is associated with Rpn11 instability and increased sensitivity to stress

Rpn11 is a proteasome-associated deubiquitinating enzyme that is essential for viability. Recent genetic studies showed that Rpn11 is functionally linked to Rpn10, a major multiubiquitin chain binding receptor in the proteasome. Mutations in Rpn11 and Rpn10 can reduce the level and/or stability of proteasomes, indicating that both proteins influence its structural integrity. To characterize the properties of Rpn11, we examined its interactions with other subunits in the 19S regulatory particle and detected strong binding to Rpn3. Two previously described rpn3 mutants are sensitive to protein translation inhibitors and an amino acid analog. These mutants also display a mitochondrial defect. The abundance of intact proteasomes was significantly reduced in rpn3 mutants, as revealed by strongly reduced binding between 20S catalytic with 19S regulatory particles. Proteasome interaction with the shuttle factor Rad23 was similarly reduced. Consequently, higher levels of multiUb proteins were associated with Rad23, and proteolytic substrates were stabilized. The availability of Rpn11 is important for maintaining adequate levels of intact proteasomes, as its depletion caused growth and proteolytic defects in rpn3. These studies suggest that Rpn11 is stabilized following its incorporation into proteasomes. The instability of Rpn11 and the defects of rpn3 mutants are apparently caused by a failure to recruit Rpn11 into mature proteasomes.     

The E3 ligase Topors induces the accumulation of polysumoylated forms of DNA topoisomerase I in vitro and in vivo

Human Topors has originally been identified as binding partner of p53 and DNA topoisomerase I (TOP1). It can function as both an ubiquitin and SUMO-1 E3 ligase for p53. Here we demonstrate that Topors enhances the formation of high-molecular weight SUMO-1 conjugates of TOP1 in a reconstituted in vitro system and also in human osteosarcoma cells, similar to treatment with CPT. In contrast to the situation observed with p53, overall sumoylation levels were rather unaffected. Experiments with TOP1 point mutants strongly suggest that the high-molecular weight conjugates represent SUMO-1 chains formed on a limited number of SUMO-1 acceptor sites.     

Topors acts as a SUMO-1 E3 ligase for p53 in vitro and in vivo

Human Topors, which was originally identified as cellular binding partner of DNA topoisomerase I and of p53, has recently been shown to function as an ubiquitin E3 ligase for p53 in a manner dependent on its N'-terminally located RING finger. Here, we demonstrate that Topors also enhances the conjugation of the small ubiquitin-like modifier 1 (SUMO-1) to p53 in vivo and in a reconstituted in vitro system. The Topors SUMO-1 E3 ligase activity does not depend upon its RING finger motif. In HeLa cells, Topors induced p53 sumoylation was accompanied by an increase in endogenous p53 protein levels. Furthermore, Topors enhances the sumoylation of a variety of other, yet unidentified, cellular proteins.     

Penicillin-binding protein 2x of Streptococcus pneumoniae: three new mutational pathways for remodelling an essential enzyme into a resistance determinant

Mutations in the transpeptidase domain of penicillin-binding protein 2x (PBP2x) of Streptococcus pneumoniae that reduce the affinity to beta-lactams are important determinants of resistance to these antibiotics. We have now analyzed in vitro and in vivo properties of PBP2x variants from cefotaxime-resistant laboratory mutants and a clinical isolate. The patterns of two to four resistance-specific mutations present in each of the proteins, all of which are placed between 6.6 and 24 Å around the active site, fall into three categories according to their positions in the three-dimensional structure. The first PBP2x group is characterized by mutations at the end of helix α11 and carries the well-known T550A change and/or one mutation on the surface of the penicillin-binding domain in close contact with the C-terminal domain. All group I proteins display very low acylation efficiencies, ≤ 1700 M^− 1 s^− 1, for cefotaxime. The second class represented by PBP2x of the mutant C505 shows acylation efficiencies below 100 M^− 1 s^− 1 for both cefotaxime and benzylpenicillin and contains the mutation L403F at a critical site close to the active serine. PBP2x of the clinical isolate 669 reveals a third mutational pathway where at least the two mutations Q552E and S389L are important for resistance, and acylation efficiency is reduced for both beta-lactams to around 10,000 M^− 1 s^− 1. In each group, at least one mutation is located in close vicinity to the active site and mediates a resistance phenotype in vivo alone, whereas other mutations might exhibit secondary effects only in context with other alterations.     

Thymosin beta4 is involved in stabilin-2-mediated apoptotic cell engulfment

Stabilin-2 was recently identified as a novel receptor for membrane phosphatidylserine of apoptotic cells. To identify proteins that were candidates for stabilin-2 cytoplasmic domain binding, we screened a human spleen cDNA library using the yeast two-hybrid system. We found that thymosin beta4 interacts with the stabilin-2 cytoplasmic domain and is co-localized with stabilin-2 at the phagocytic cup. Knockdown of thymosin beta4 significantly decreased the phagocytic activity of stabilin-2, whereas overexpression of thymosin beta4 increased this activity. Additionally, amino acids 2504-2514 of stabilin-2 cytoplasmic domain were found to be responsible for the interaction with thymosin beta4. Taken together, these results suggest that thymosin beta4 is a downstream molecule of stabilin-2 that plays a role in stabilin-2-mediated cell corpse clearance.     

Circadian clock genes period and cycle regulate photoperiodic diapause in the bean bug Riptortus pedestris males

The photoperiodic response is crucial for many insects to adapt to seasonal changes in temperate regions. It was recently shown that the circadian clock genes period (per) and cycle (cyc) are involved in the photoperiodic regulation of reproductive diapause in the bean bug Riptortus pedestris females. Here, we investigated the involvement of per and cyc both in the circadian rhythm of cuticle deposition and in the photoperiodic diapause of R. pedestris males using RNA interference (RNAi). RNAi of per and cyc disrupted the cuticle deposition rhythm and resulted in distinct cuticle layers. RNAi of per induced development of the male reproductive organs even under diapause-inducing short-day conditions, whereas RNAi of cyc suppressed development of the reproductive organs even under diapause-averting long-day conditions. Thus, the present study suggests that the circadian clock operated by per and cyc governs photoperiodism of males as that of females.     

PUF3 Acceleration of Deadenylation in Vivo Can Operate Independently of CCR4 Activity, Possibly Involving Effects on the PAB1-mRNP Structure

The evolutionarily conserved PUF proteins stimulate CCR4 mRNA deadenylation through binding to 3′ untranslated region sequences of specific mRNA. We have investigated the mechanisms by which PUF3 in Saccharomyces cerevisiae accelerates deadenylation of the COX17 mRNA. PUF3 was shown to affect PAN2 deadenylation of the COX17 mRNA independent of the presence of CCR4, suggesting that PUF3 acts through a general mechanism to affect deadenylation. Similarly, eIF4E, the cap-binding translation initiation factor known to control CCR4 deadenylation, was shown to affect PAN2 activity in vivo. PUF3 was found to be required for eIF4E effects on COX17 deadenylation. Both eIF4E and PUF3 effects on deadenylation were shown, in turn, to necessitate a functional poly(A)-binding protein (PAB1) in which removal of the RRM1 (RNA recognition motif 1) domain of PAB1 blocked both their effects on deadenylation. While removal of the proline-rich region (P domain) of PAB1 substantially reduces CCR4 deadenylation at non-PUF3-controlled mRNA and correspondingly blocked eIF4E effects on deadenylation, PUF3 essentially bypassed this P domain requirement. These results indicate that the PAB1-mRNP structure is critical for PUF3 action. We also found that multiple components of the CCR4-NOT deadenylase complex, but not PAN2, interacted with PUF3. PUF3 appears, therefore, both to act independently of CCR4 activity, possibly through effects on PAB1-mRNP structure, and to be capable of retaining the CCR4-NOT complex.     

Molecular characterization of two homologs of the Caenorhabditis elegans cadmium-responsive gene cdr-1: cdr-4 and cdr-6

A novel cadmium-inducible gene, cdr-1, was previously identified and characterized in the nematode Caenorhabditis elegans and found to mediate resistance to cadmium toxicity. Subsequently, six homologs of cdr-1 were identified in C. elegans. Here, we describe two homologs: cdr-4, which is metal inducible, and cdr-6, which is noninducible. Both cdr-4 and cdr-6 mRNAs contain open reading frames of 831 nt and encode predicted 32-kDa integral membrane proteins, which are similar to CDR-1. cdr-4 expression is induced by arsenic, cadmium, mercury, and zinc exposure as well as by hypotonic stress. In contrast, cdr-6 is constitutively expressed at a high level in C. elegans, and expression is not affected by these stressors. Both cdr-4 and cdr-6 are transcribed in postembryonic pharyngeal and intestinal cells in C. elegans. In addition, cdr-4 is transcribed in developing embryos. Like CDR-1, CDR-4 is targeted to intestinal cell lysosomes in vivo. Inhibition of CDR-4 and/or CDR-6 expression does not render C. elegans more susceptible to cadmium toxicity; however, there is a significant decrease in their lifespan in the absence of metal. Although nematodes in which CDR-4 and/or CDR-6 expression is knocked down accumulate fluid in the pseudocoelomic space, exposure to hypertonic conditions did not significantly affect growth or reproduction in these nematodes. These results suggest that CDR expression is required for optimal viability but does not function in osmoregulation.     

Optimizing expression and purification of an ATP-binding gene gsiA from Escherichia coli k-12 by using GFP fusion

The cloning, expression and purification of the glutathione (sulfur) import system ATP-binding protein (gsiA) was carried out. The coding sequence of Escherichia coli gsiA, which encodes the ATP-binding protein of a glutathione importer, was amplified by PCR, and then inserted into a prokaryotic expression vector pWaldo-GFPe harboring green fluorescent protein (GFP) reporter gene. The resulting recombinant plasmid pWaldo-GFP-GsiA was transformed into various E. coli strains, and expression conditions were optimized. The effect of five E. coli expression strains on the production of the recombinant gsiA protein was evaluated. E. coli BL21 (DE3) was found to be the most productive strain for GsiA-GFP fusion-protein expression, most of which was insoluble fraction. However, results from in-gel and Western blot analysis suggested that expression of recombinant GsiA in Rosetta (DE3) provides an efficient source in soluble form. By using GFP as reporter, the most suitable host strain was conveniently obtained, whereby optimizing conditions for overexpression and purification of the proteins for further functional and structural studies, became, not only less laborious, but also time-saving.     

A Conserved Unfoldase Activity for the p97 AAA-ATPase in Proteasomal Degradation

The multifunctional AAA-ATPase p97 is one of the most abundant and conserved proteins in eukaryotic cells. The p97/Npl4/Ufd1 complex dislocates proteins that fail the protein quality control in the endoplasmic reticulum to the cytosol where they are subject to degradation by the ubiquitin/proteasome system. Substrate dislocation depends on the unfoldase activity of p97. Interestingly, p97 is also involved in the degradation of specific soluble proteasome substrates but the exact mode of action of p97 in this process is unclear. Here, we show that both the central pore and ATPase activity of p97 are necessary for the degradation of cytosolic ubiquitin-fusion substrates. Addition of a flexible extended C-terminal peptide to the substrate relieves the requirement for p97. Deletion mapping reveals a conserved length dependency of 20 residues for the peptide, which allows p97-independent degradation to occur. Our results suggest that initiation of unfolding may be more complex than previously anticipated and that the 19S regulatory complex of the proteasome can require preprocessing of highly folded, ubiquitylated substrates by the p97^Ufd1/Npl4 complex. Our data provide an explanation for the observation that p97 is only essential for a subpopulation of soluble substrates and predict that a common characteristic of soluble p97-dependent substrates is the lack of an initiation site to facilitate unfolding by the 26S proteasome.     

Requirement of the transmembrane semaphorin Sema4C for myogenic differentiation

Semaphorins constitute a large family of signaling proteins that contribute to axonal guidance. Here we demonstrate that the transmembrane semaphorin Sema4C is up-regulated both in the early stage of differentiation of C2C12 mouse skeletal myoblasts into myotubes and during injury-induced muscle regeneration in vivo. Depletion of Sema4C in C2C12 cells resulted in marked attenuation of myotube formation. A fusion protein containing the extracellular Sema domain and a peptide corresponding to the intracellular COOH-terminal region of Sema4C each inhibited the differentiation of C2C12 cells. These findings indicate that Sema4C-mediated interaction among myoblasts plays an important role in terminal myogenic differentiation.