Localization to the proteasome is sufficient for degradation

The majority of unstable proteins in eukaryotic cells are targeted for degradation through the ubiquitin-proteasome pathway. Substrates for degradation are recognized by the E1, E2, and E3 ubiquitin conjugation machinery and tagged with polyubiquitin chains, which are thought to promote the proteolytic process through their binding with the proteasome. We describe a method to bypass the ubiquitination step artificially both in vivo and in a purified in vitro system. Seven proteasome subunits were tagged with Fpr1, and fusion reporter constructs were created with the Fpr1-rapamycin binding domain of Tor1. Reporter proteins were localized to the proteasome by the addition of rapamycin, a drug that heterodimerizes Fpr1 and Tor1. Degradation of reporter proteins was observed with proteasomes that had either Rpn10 or Pre10 subunits tagged with Fpr1. Our experiments resolved a simple but central problem concerning the design of the ubiquitin-proteasome pathway. We conclude that localization to the proteasome is sufficient for degradation and, therefore, any added functions polyubiquitin chains possess beyond tethering substrates to the proteasome are not strictly necessary for proteolysis.     

Alsin is partially associated with centrosome in human cells

Mutations in the ALS2 gene has recently been linked to cases of juvenile amyotrophic lateral sclerosis, juvenile primary lateral sclerosis and ascending hereditary spastic paralysis. All reported mutations predict the production of truncated forms of Alsin suggesting a loss of function mechanism for these motor neuron disorders. Here we used the tetracycline-regulated expression system to overexpress the full-length and truncated forms of Alsin in different cell lines. Alsin overexpression caused severe phenotypic changes in monkey COS-7 cells including the enlargement and accumulation of early endosomes, impairment of mitochondria trafficking and fragmentation of the Golgi apparatus. Our results further demonstrate the requirement of the Alsin VPS9 domain for occurrence of the vacuolation process and the role of Alsin as a guanine nucleotide exchange factor for Rab5. Transfected human SW13 cells exhibited an unexpected centrosomal localization for Alsin that was linked to the presence of the c-terminal part of the protein. Immunofluorescence staining revealed a colocalization of Alsin with the centrosomal markers gamma-tubulin and A kinase anchoring protein (AKAP-450). Similar results were obtained with human LA-N-2 and SK-N-SH neuronal cells. Moreover endogenous Alsin was detected in a centrosome preparation purified from human cortical brain. Considering the crucial role of centrosome in the production of microtubules required for intracellular transport, these findings are of potential relevance for unravelling the disease mechanisms linked to Alsin mutations.     

Enolase is present at the centrosome of HeLa cells.

Antibodies raised against the C-terminus and N-terminus region of gamma gamma enolase, as well as a polyclonal antibody raised against bovine brain gamma gamma enolase, were used to study the distribution of this glycolytic enzyme during the cell cycle in HeLa cells. Enolase was found to be present throughout the cytoplasm of both interphase and dividing cells. In addition, a portion of cellular enolase was detected at the centrosome throughout the cell cycle. The capacity of glycolytic enzymes to play a structural as well as a glycolytic role suggests that the presence of enolase at the centrosome may be correlated with the organization of both the interphase cytoskeleton and the mitotic spindle.     

Determinants of Rad21 localization at the centrosome in human cells

Cohesin proteins help maintain the physical associations between sister chromatids that arise in S-phase and are removed in anaphase. Recent studies found that cohesins also localize to the centrosomes, the organelles that organize the mitotic bipolar spindle. We find that the cohesin protein Rad21 localizes to centrosomes in a manner that is dependent upon known regulators of sister chromatid cohesion as well as regulators of centrosome function. These data suggest that Rad21 functions at the centrosome and that the regulators of Rad21 coordinate the centrosome and chromosomal functions of cohesin.     

Alpha-lactalbumin unfolding is not sufficient to cause apoptosis, but is required for the conversion to HAMLET (human alpha-lactalbumin made lethal to tumor cells)

HAMLET (human alpha-lactalbumin made lethal to tumor cells) is a complex of human alpha-lactalbumin and oleic acid (C18:1:9 cis) that kills tumor cells by an apoptosis-like mechanism. Previous studies have shown that a conformational change is required to form HAMLET from alpha-lactalbumin, and that a partially unfolded conformation is maintained in the HAMLET complex. This study examined if unfolding of alpha-lactalbumin is sufficient to induce cell death. We used the bovine alpha-lactalbumin Ca(2+) site mutant D87A, which is unable to bind Ca(2+), and thus remains partially unfolded regardless of solvent conditions. The D87A mutant protein was found to be inactive in the apoptosis assay, but could readily be converted to a HAMLET-like complex in the presence of oleic acid. BAMLET (bovine alpha-lactalbumin made lethal to tumor cells) and D87A-BAMLET complexes were both able to kill tumor cells. This activity was independent of the Ca(2+)site, as HAMLET maintained a high affinity for Ca(2+) but D87A-BAMLET was active with no Ca(2+) bound. We conclude that partial unfolding of alpha-lactalbumin is necessary but not sufficient to trigger cell death, and that the activity of HAMLET is defined both by the protein and the lipid cofactor. Furthermore, a functional Ca(2+)-binding site is not required for conversion of alpha-lactalbumin to the active complex or to cause cell death. This suggests that the lipid cofactor stabilizes the altered fold without interfering with the Ca(2+)site.     

Increased expression of VEGF in retinal pigmented epithelial cells is not sufficient to cause choroidal neovascularization

Increased expression of vascular endothelial cell growth factor (VEGF) in the retina is sufficient to stimulate sprouting of neovascularization from the deep capillary bed of the retina, but not the superficial retinal capillaries or the choriocapillaris. Coexpression of VEGF and angiopoietin 2 (Ang2) results in sprouting of neovascularization from superficial and deep retinal capillaries, but not the choriocapillaris. However, retina-derived VEGF and Ang2 may not reach the choriocapillaris, because of tight junctions between retinal pigmented epithelial (RPE) cells. To eliminate this possible confounding factor, we used the human vitelliform macular dystrophy 2 (VMD2) promoter, an RPE-specific promoter, combined with the tetracycline-inducible promoter system, to generate double transgenic mice with inducible expression of VEGF in RPE cells. Adult mice with increased expression of VEGF in RPE cells had normal retinas and choroids with no choroidal neovascularization (CNV), but when increased expression of VEGF in RPE cells was combined with subretinal injection of a gutless adenoviral vector containing an expression construct for Ang2 (AGVAng2), CNV consistently occurred. In contrast, triple transgenic mice with induced expression of Ang2 and VEGF in RPE cells, did not develop CNV. These data suggest that increased expression of VEGF and/or Ang2 in RPE cells is not sufficient to cause CNV unless it is combined with a subretinal injection of a gutless adenoviral vector, which is likely to perturb RPE cells. These data also suggest that the effects of angiogenic proteins may vary among vascular beds, even those that are closely related, and, therefore, generalizations should be avoided.     

Estrogen receptor activation at serine 305 is sufficient to upregulate cyclin D1 in breast cancer cells

Recent studies have shown that p21-activated kinase 1 (Pak1) phosphorylates estrogen receptor-alpha (ER alpha) at Ser 305 and also promotes its transactivation function. Here, we sought to investigate whether substitution of serine 305 in ER with glutamic acid (ER alpha-S305E), which mimics the phosphorylation state, would influence the status of ER-target genes. To explore this possibility, we generated clones overexpressing ER alpha-S305E in ER-negative MDA-MB-231 cells and analyzed the status of ER-regulated genes using a gene array. Results indicated that the expression of ER alpha-S305E is sufficient to upregulate the expression of a few but not all ER-regulated genes, i.e., cyclin D1 and zinc finger protein 147 (estrogen-responsive finger protein), while there was no significant change in the expression of remaining genes on the array. In addition, we found an increased expression as well as nuclear accumulation of cyclin D1 protein in MDA-MB-231 cells expressing ER alpha-S305E as compared to the level of cyclin D1 in MDA-MB-231 cells expressing WT-ER alpha or pcDNA. Furthermore, ER alpha-S305E, but not mutation of ER alpha-S305 to alanine, enhanced the cyclin D1 promoter activity. These findings suggest that ER alpha activation at S305 is sufficient to upregulate the expression of cyclin D1, an ER-regulated gene that is implicated in the progression of breast cancer. Phosphorylation of ER alpha by Pak1 or its upstream regulators could upregulate the expression of a subset of ER-target genes in a ligand-independent manner and hence, might contribute toward the development of hormone independence in breast cancer cells.     

Mutant myocilin nonsecretion in vivo is not sufficient to cause glaucoma

Glaucoma is a leading cause of blindness, affecting over 70 million people worldwide. Vision loss is the result of death of the retinal ganglion cells. The best-known risk factor for glaucoma is an elevated intraocular pressure (IOP); however, factors leading to IOP elevation are poorly understood. Mutations in the MYOC gene are an important cause of open-angle glaucoma. Over 70 MYOC mutations have been identified, and they lead to approximately 5% of all primary open-angle glaucoma cases. Nevertheless, the pathogenic mechanisms by which these mutations elevate IOP are presently unclear. Data suggest that a dominant interfering effect of misfolded mutant MYOC molecules may be pathogenic. To test this hypothesis, we have generated mice carrying a mutant allele of Myoc that is analogous to a human mutation that leads to aggressive glaucoma in patients. We show that mutant MYOC is not secreted into the aqueous humor. Instead of being secreted, mutant MYOC accumulates within the iridocorneal angle of the eye, consistent with the behavior of abnormally folded protein. Surprisingly, the accumulated mutant protein does not activate the unfolded protein response and lead to elevated intraocular pressure or glaucoma in aged mice of different strains. These data suggest that production, apparent misfolding, and nonsecretion of mutant MYOC are not, by themselves, sufficient to cause glaucoma in vivo.     

Cytoplasmic dynein is involved in the retention of microtubules at the centrosome in interphase cells

Cytoplasmic dynein is known to be involved in the establishment of radial microtubule (MT) arrays. During mitosis, dynein activity is required for tethering of the MTs at the spindle poles. In interphase cells, dynein inhibitors induce loss of radial MT organization; however, the exact role of dynein in the maintenance of MT arrays is unclear. Here, we examined the effect of dynein inhibitors on MT distribution and the centrosome protein composition in cultured fibroblasts. We found that while these inhibitors induced rapid ( t _1/2 ∼ 20 min) loss of radial MT organization, the levels of key centrosomal proteins or the rates of MT nucleation did not change significantly in dynein-inhibited cells, suggesting that the loss of dynein activity does not affect the structural integrity of the centrosome or its capacity to nucleate MTs. Live observations of the centrosomal activity showed that dynein inhibition enhanced the detachment of MTs from the centrosome. We conclude that the primary role of dynein in the maintenance of a radial MT array in interphase cells consists of retention of MTs at the centrosome and hypothesize that dynein has a role in the MT retention, separate from the delivery to the centrosome of MT-anchoring proteins.     

hsp70 is localized to the centrosome of dividing HeLa cells

Monoclonal antibodies specific for inducible and constitutive members of the hsp70 family have been used to investigate the distribution of these proteins during the cell cycle of HeLa cells with special reference to mitosis. Indirect immunofluorescence studies illustrate that a portion of the constitutive form, hsp73, is localized to the centrosome during cell division. In addition a subset of the inducible form, hsp72, collects at the centrosome of dividing cells following heat shock. These observations suggest that members of the hsp70 family are cell cycle specific components of the centrosome in HeLa cells and may play an important role in the function of this microtubule organizing center.     

Abnormal glycogen in astrocytes is sufficient to cause adult polyglucosan body disease

Background

A 45-year old woman of Cambodian ethnic background presented with fatal respiratory failure due to a severe diaphragmatic dysfunction. Two years before, she had developed early onset of urinary symptoms.

Methods and results

Neuroimaging showed atrophy of the spine and medulla as well as a leukodystrophy affecting both supra- and infra-tentorial regions. At autopsy, polyglucosan bodies (PB) were seen in several peripheral tissues, including the diaphragm, and nervous tissues such as peripheral nerves, cerebral white matter, basal ganglia, hippocampus, brainstem and cerebellum. Immunohistochemistry and electron microscopy of the brain revealed an exclusive astrocytic localization of the PB. The diagnosis of adult polyglucosan body disease (APBD) was confirmed by enzymatic and molecular studies.

Conclusion

Storage of abnormal glycogen in astrocytes is sufficient to cause the leukodystrophy of APBD. Since brain glycogen is almost exclusively metabolized in astrocytes, this observation sheds light on the pathophysiology of APBD. In addition, this is the first report of an APBD patient presenting with a subacute diaphragmatic failure.     

Histone hyperacetylation induced by histone deacetylase inhibitors is not sufficient to cause growth inhibition in human dermal fibroblasts

Use of specific histone deacetylase inhibitors has revealed critical roles for the histone deacetylases (HDAC) in controlling proliferation. Although many studies have correlated the function of HDAC inhibitors with the hyperacetylation of histones, few studies have specifically addressed whether the accumulation of acetylated histones, caused by HDAC inhibitor treatment, is responsible for growth inhibition. In the present study we show that HDAC inhibitors cause growth inhibition in normal and transformed keratinocytes but not in normal dermal fibroblasts. This was despite the observation that the HDAC inhibitor, suberic bishydroxamate (SBHA), caused a kinetically similar accumulation of hyperacetylated histones. This cell type-specific response to SBHA was not due to the inactivation of SBHA by fibroblasts, nor was it due to differences in the expression of specific HDAC family members. Remarkably, overexpression of HDACs 1, 4, and 6 in normal human fibroblasts resulted in cells that could be growth-inhibited by SBHA. These data suggest that, although histone acetylation is a major target for HDAC inhibitors, the accumulation of hyperacetylated histones is not sufficient to cause growth inhibition in all cell types. This suggests that growth inhibition, caused by HDAC inhibitors, may be the culmination of histone hyperacetylation acting in concert with other growth regulatory pathways.     

Chronology of chromosome reduplication in Chinese hamster cells incubated at low temperature

Experiments have been carried out on Chinese hamster fibroblasts. Cultures at the log-stage of growth were incubated at 15 or 25° C for 24 hrs. In two groups of experiments the cells were labeled with H³-TdR for 6 hrs at the respective temperature, washed and further incubated at 37° C. In each group of experiments cultures labeled with H³-TdR at 37° C for 20 min were used as a control. It was found: 1. the delay in the onset of cell passage through the mitotic cycle at 37° in cultures exposed to 15 or 25° C was about equal to 1,5-1 hr resp. and cells proceeded through the life cycle without blockages at any phase of the cycle; 2. the patterns of chromosome reproduction during the second half of the S-phase were the same after labeling at 15, 25 and 37° C. — In the third group the cells were labelled with HP-TdR for 10–60 min and 6 hrs resp. at 25° C. The patterns of reproduction of chromosome pairs 1–4 and small metacentrics were found to be the same in cells labeled briefly and those labeled for 6 hrs. After brief labeling asynchronous reduplication of different segments in many chromosomes became evident. It was masked because of heavy labeling after 6 hrs treatment.     

Geminin is partially localized to the centrosome and plays a role in proper centrosome duplication

Background information. Centrosome duplication normally parallels with DNA replication and is responsible for correct segregation of replicated DNA into the daughter cells. Although geminin interacts with Cdt1 to prevent loading of MCMs (minichromosome maintenance proteins) on to the replication origins, inactivation of geminin nevertheless causes centrosome over‐duplication in addition to the re‐replication of the genome, suggesting that geminin may play a role in centrosome duplication. However, the exact mechanism by which loss of geminin affects centrosomal duplication remains unclear and the possible direct interaction of geminin with centrosomal‐localized proteins is still unidentified. Results. We report in the present study that geminin is physically localized to the centrosome. This unexpected geminin localization is cell‐cycle dependent and mediated by the actin‐related protein, Arp1, one subunit of the dynein—dynactin complex. Disruption of the integrity of the dynein—dynactin complex by overexpression of dynamitin/p50, a well‐characterized inhibitor of dynactin, reduces the centrosomal localization of both geminin and Arp1. Enrichment of geminin on centrosomes was enhanced when cellular ATP production was suppressed in the ATP‐inhibitor assay, whereas the accumulation of geminin on the centrosome was disrupted by depolymerization of the microtubules using nocodazole. We further demonstrate that the coiled‐coil motif of geminin is required for its centrosomal localization and the interaction of geminin with Arp1. Depletion of geminin by siRNA (small interfering RNA) in MDA‐MB‐231 cells led to centrosome over‐duplication. Conversely, overexpression of geminin inhibits centrosome over‐duplication induced by HU in S‐phase‐arrested cells, and the coiled‐coil‐motif‐mediated centrosomal localization of geminin is required for its inhibition of centrosome over‐duplication. Centrosomal localization of geminin is conserved among mammalian cells and geminin might perform as an inhibitor of centrosome duplication. Conclusions. The results of the present study demonstrate that a fraction of geminin is localized on the centrosome, and the centrosomal localization of geminin is Arp1‐mediated and dynein—dynactin‐dependent. The coiled‐coil motif of geminin is required for its targeting to the centrosome and inhibition of centrosome duplication. Thus the centrosomal localization of geminin might perform an important role in regulation of proper centrosome duplication.     

Translocation of XRCC1 and DNA ligase IIIalpha from centrosomes to chromosomes in response to DNA damage in mitotic human cells

DNA single-strand breaks (SSBs) are the most frequent lesions caused by oxidative DNA damage. They disrupt DNA replication, give rise to double-strand breaks and lead to cell death and genomic instability. It has been shown that the XRCC1 protein plays a key role in SSBs repair. We have recently shown in living human cells that XRCC1 accumulates at SSBs in a fully poly(ADP-ribose) (PAR) synthesis-dependent manner and that the accumulation of XRCC1 at SSBs is essential for further repair processes. Here, we show that XRCC1 and its partner protein, DNA ligase IIIα, localize at the centrosomes and their vicinity in metaphase cells and disappear during anaphase. Although the function of these proteins in centrosomes during metaphase is unknown, this centrosomal localization is PAR-dependent, because neither of the proteins is observed in the centrosomes in the presence of PAR polymerase inhibitors. On treatment of metaphase cells with H₂O₂, XRCC1 and DNA ligase IIIα translocate immediately from the centrosomes to mitotic chromosomes. These results show for the first time that the repair of SSBs is present in the early mitotic chromosomes and that there is a dynamic response of XRCC1 and DNA ligase IIIα to SSBs, in which these proteins are recruited from the centrosomes, where metaphase-dependent activation of PAR polymerase occurs, to mitotic chromosomes, by SSBs-dependent activation of PAR polymerase.     

RNA1 is sufficient to mediate plasmid ColE1 incompatibility in vivo

The multicopy plasmid ColE1 specifies a small RNA designated RNA1 that has been implicated in copy number control and incompatibility. We have inserted a 148 base-pair ColE1 DNA fragment containing a promoter-less RNA1 gene into a plasmid vector downstream from the tryptophan promoter of Serratia marcesens. The ColE1 RNA1 produced by this plasmid is not functional in vivo due to the presence of 49 nucleotides appended to the 5′-terminus of the wild-type RNA1 sequence. Deletions of these sequences by Bal3I nuclease in vitro and genetic selection for ColE1 incompatibility function in vivo permitted isolation of a plasmid expressing wild-type ColE1 RNA1 initiated properly from the S. marcesens trp promoter. These experiments demonstrate that RNA1 is sufficient to mediate ColE1 incompatibility in vivo. In addition, several plasmids were isolated that contain altered RNA1 genes. These alterations consist of additions or deletions of sequences at the 5′-terminus of RNA1. Analysis of the ability of these altered RNA1 molecules to express incompatibility in vivo suggests that the 5′-terminal region of RNA1 is crucial for its function.