Control of simian virus 40 DNA replication by the HeLa cell nuclear kinase casein kinase I.

The initiation of simian virus 40 (SV40) DNA replication is regulated by the phosphorylation state of the viral initiator protein, large T antigen. We describe the purification from HeLa cell nuclei of a 35-kDa serine/threonine protein kinase that phosphorylates T antigen at sites that are phosphorylated in vivo and thereby inhibits its ability to initiate SV40 DNA replication. The inhibition of both origin unwinding and DNA replication by the kinase is reversed by protein phosphatase 2A. As determined by molecular weight, substrate specificity, autophosphorylation, immunoreactivity, and limited sequence analysis, this kinase appears to be identical to casein kinase I, a ubiquitous serine/threonine protein kinase that is closely related to a yeast kinase involved in DNA metabolism. The HeLa cell phosphorylation cycle that controls the initiation of SV40 DNA replication may also play a role in cellular DNA metabolism.

Different oligomeric forms of protein phosphatase 2A activate and inhibit simian virus 40 DNA replication.

The ability of simian virus 40 (SV40) large T antigen to catalyze the initiation of viral DNA replication is regulated by its phosphorylation state. Previous studies have identified the free catalytic subunit of protein phosphatase 2A (PP2Ac) as the cellular phosphatase which can remove inhibitory phosphoryl groups from serines 120 and 123. The catalytic C subunit exists in the cell complexed with a 65-kDa A subunit and one of several B subunits. To determine if any of the holoenzymes could activate T antigen, we tested the ability of the heterodimeric AC and two heterotrimeric ABC forms to stimulate T-antigen function in unwinding the origin of SV40 DNA replication. Only free catalytic subunit C and the heterotrimeric form with a 72-kDa B subunit (PP2A-T72) could stimulate T-antigen-dependent origin unwinding. Both the dimeric form (PP2A-D) and the heterotrimer with a 55-kDa B subunit (PP2A-T55) actively inhibited T-antigen function. We found that PP2A-T72 activated T antigen by dephosphorylating serines 120 and 123, while PP2A-D and PP2A-T55 inactivated T antigen by dephosphorylating the p34cdc2 target site, threonine 124. Thus, alterations in the subunit composition of PP2A holoenzymes have significant functional consequences for the initiation of in vitro SV40 DNA replication. The regulatory B subunits of PP2A may play a role in regulating SV40 DNA replication in infected cells as well.

Association Between HLA Type and Skin Cancer in Kidney Transplant Recipients.

BACKGROUND: Organ transplant recipients (OTRs) are more susceptible to various diseases, among them cancers. Nonmelanoma skin cancers (NMSC) represent the most common malignancies in OTRs in Europe. Due to the significantly higher morbidity, aggressive and rapid progression, and poor prognosis of NMSC in the OTR population, these patients require a special oncological approach. Intensive attention should therefore be paid to factors predisposing OTRs to the development of cancer. The aim of this study was to establish the role of genetic factors in the pathogenesis of skin cancer in kidney transplant recipients (KTRs). METHODS: This single-center study was performed in 39 KTRs with posttransplant NMSC. The frequency of particular types of HLA Class I (HLA-A and HLA-B) and Class II (HLA-DR) in each group were compared to establish the association between the HLA type and risk of skin cancer after renal transplantation. RESULTS: HLA-DR15 were more commonly detected in patients with MNSC than in the control group of KTRs (P = .014) There was also a positive correlation between HLA-B18 and skin squamous cell carcinoma. The antigen was more often recorded in KTRs with squamous cell carcinoma than in KTRs without NMSC (P = .03) and in the general population (P = .002). CONCLUSIONS: Patients who are positive for HLA-BR15 and HLA-B18 should be under special dermatologic surveillance due to the potentially high risk of skin cancer.

Isolation and characterization of an Escherichia coli DnaK mutant with impaired ATPase activity.

A temperature-sensitive mutant of DnaK, the principal Escherichia coli member of the 70 kDa heat shock protein family, has been isolated. The mutation, dnaK25, lies in the putative ATP binding pocket of DnaK. It consists of a C to T transition that changes the highly conserved proline 143 to serine. Mutant strains do not support the propagation of bacteriophage lambda or of plasmids that require DnaA for replication. They are also defective in the utilization of mannose and sorbitol. ATPase activity of the mutant protein is reduced 20-fold relative to wild-type, while autophosphorylation is unaffected. DnaK25 has a fourfold faster rate of nucleotide exchange than wild-type DnaK; nucleotide exchange by both proteins is markedly increased by GrpE. The DnaK25 ATPase is still stimulated by DnaJ and GrpE and by peptide substrates. However, the affinity of most peptides tested for stimulating the DnaK25 ATPase is reduced significantly. These results indicate that a mutation in the N-terminal nucleotide binding domain can alter substrate interactions with the C-terminal substrate binding site. Nucleotide exchange by both wild-type DnaK and DnaK25 proceeds at a much faster rate than ATP hydrolysis, and therefore cannot be the rate limiting step of ATP hydrolysis under the conditions used in these experiments. Consistent with this, peptides, which stimulate ATP hydrolysis, have no effect on nucleotide exchange. Peptides thus appear to stimulate the ATPase by acting at another step, such as increasing the rate of phosphate bond cleavage.

Biochemical properties of the Escherichia coli dnaK heat shock protein and its mutant derivatives.

The dnaK protein of Escherichia coli has been shown to possess both autophosphorylating and 5'-nucleotidase activities. The dnaK protein has been shown to bind avidly to ATP, but hydrolyzing it slowly. In vitro autophosphorylation occurs at a threonine residue when either ATP or GTP are used as phosphate donors. The extent of autophosphorylation is low; only a few percent of the molecules are phosphorylated. This activity is stimulated at least tenfold in the presence of Ca2+ ions with either ATP or GTP as the donor. The autophosphorylating activity of the mutant dnaK756 protein in the presence or absence of Ca2+ is reduced compared to that of the wild type.

Human papillomavirus-related verrucous carcinoma in a renal transplant patient after long-term immunosuppression: a case report.

BACKGROUND: Verrucous carcinoma is a slow-growing tumor with 3 main localizations: Oral cavity, ano-urogenital region, and plantar surface of the foot. On the sole it may rise adjacent to viral warts and very often is mistaken for the common verruca plantaris. Although both conditions-viral warts and cutaneous squamous cell carcinoma-are often diagnosed in immunosuppressed patients, in literature we have found only 3 case reports of verrucous carcinoma in organ transplant recipients. CASE REPORT: We present a case of 26-year-old man after deceased donor renal transplantation with plantar verrucous carcinoma successfully treated with excision and 5% imiquimod.

Functional domains of the Escherichia coli dnaK heat shock protein as revealed by mutational analysis.

The employment of a set of truncated dnaK peptides produced by deletion and insertion mutations in the Escherichia coli dnaK gene allowed us to define regions of the dnaK protein which are involved in particular enzymatic functions. The results obtained suggest that the dnaK polypeptide is organized into at least two distinct functional domains. The highly conserved amino-terminal portion is required for the ATPase activity. The carboxyl-terminal portion, characterized by relatively low similarity among species, is responsible for the autophosphorylating activity. The mutant dnaK protein C[74], which lacks amino acid sequences at the extreme carboxyl-terminal portion of the protein, retains both the ATPase and the autophosphorylating activities. The results obtained with the full-length (70-kDa) dnaK756 protein suggest that the thermolabile defect of the dnaK756 mutation affects directly or indirectly the ATPase active site of the enzyme. The autophosphorylating activity of the dnaK+, dnaK756, and C[74] polypeptides was activated at least 10-fold by the addition of CaCl2.

The sfiA11 mutation prevents filamentation in a response to cell wall damage only in a recA+ genetic background.

N-alpha-palmitoyl-L-lysyl-L-lysine dihydrochloride ethyl ester (PLL) at sublethal doses causes filamentous growth of E. coli strains except sfiA mutants, which divide normally in its presence. PLL does not elicit the SOS responses as judged by lambda prophage induction, an increase of RecA protein synthesis or induction of the sfiA operon in a sfiA::lacZ fusion strain. Thus, it appears that filamentation caused by PLL is not an SOS function and might be the result of membrane damage by PLL, which is an amphipathic compound and at higher doses causes cell lysis. This indicates that basal levels of the sfiA gene product are sufficient to inhibit cell division in the presence of PLL. We have found further that the phenotype of the sfiA mutation in the presence of PLL requires a recA+ genetic background and does not occur in E. coli recA1 sfiA11, recA13 sfiA11, recA56 sfiA11 and recA441 sfiA11. All these strains, but rec441 sfiA11, however, regain the ability of sfiA11 mutants to divide in the presence of PLL after transformation with the RecA overproducing-plasmid pXO2. This supports the conclusion that the RecA protein positively affects sfiA11-mediated cell division in the presence of the cell membrane damaging compound, PLL. The basal level of the RecA protein in the recA+ sfiA11 strain is sufficient for this process. An increased level due to overproduction from the multicopy plasmid pXO2 exerts the same effect.

Role of Escherichia coli heat shock proteins DnaK and HtpG (C62.5) in response to nutritional deprivation.

Because of the highly conserved pattern of expression of the eucaryotic heat shock genes hsp70 and hsp84 or their cognates during sporulation in Saccharomyces cerevisiae and development in higher organisms, the role of the Escherichia coli homologs dnaK and htpG was examined during the response to starvation. The htpG deletion mutant was found to be similar to its wild-type parent in its ability to survive starvation for essential nutrients and to induce proteins specific to starvation conditions. The dnaK103 mutant, however, was highly susceptible to killing by starvation for carbon and, to a lesser extent, for nitrogen and phosphate. Analysis of proteins induced under starvation conditions on two-dimensional gels showed that the dnaK103 mutant was defective for the synthesis of some proteins induced in wild-type cells by carbon starvation and of some proteins induced under all starvation conditions, including the stationary phase in wild-type cells. In addition, unique proteins were synthesized in the dnaK103 mutant in response to starvation. Although the synthesis of some proteins under glucose starvation control was drastically affected by the dnaK103 mutation, the synthesis of proteins specifically induced by nitrogen starvation was essentially unaffected. Similarly, the dnaK103 mutant was able to grow, utilizing glutamine or arginine as a source of nitrogen, at a rate approximate to that of the wild-type parent, but it inefficiently utilized glycerol or maltose as carbon sources. Several differences between the protein synthetic pattern of the dnaK103 mutant and the wild type were observed after phosphate starvation, but these did not result in a decreased ability to survive phosphate starvation, compared with nitrogen starvation.

Specific response of Escherichia coli K12 sfiA mutants to the presence of ethyl ester of N-alpha-palmitoyl-L-lysyl-L-lysine dihydrochloride (PLL) in a nutrient medium.

N-alpha-palmitoyl-L-lysyl-L-lysine dihydrochloride ethyl ester (PLL) in sublethal doses (6--12.5 microgram/ml) inhibits cell division in E. coli K12 strains C600, JM1, and derivatives of JM1 carrying mutations tif-1, tif-1, sfiA, tif-1 sfiB and sfiB in conditions which do not induces SOS functions. Only sfiA mutants divide normally in the presence of PLL. This response enables direct discrimination between phenotypes of sfiA and sfiB and moreover, also the selection of spontaneous mutants sfiA in a tif+ (recA+) genetic background. The PLL mediated inhibition of cell division in tif-1 sfiA double mutants may indicate that the recA gene product plays a role in the restoration of cell division by sfiA.

T-antigen kinase inhibits simian virus 40 DNA replication by phosphorylation of intact T antigen on serines 120 and 123.

Simian virus 40 (SV40) DNA replication begins after two large T-antigen hexamers assemble on the viral minimal origin of replication and locally unwind the template DNA. The activity of T antigen in this reaction is regulated by its phosphorylation state. A form of casein kinase I purified from HeLa nuclear extracts (T-antigen kinase) phosphorylates T antigen on physiologic sites and inhibits its activity in the unwinding reaction (A. Cegielska and D. M. Virshup, Mol. Cell. Biol. 13:1202-1211, 1993). Using a series of mutant T antigens expressed by recombinant baculoviruses in Sf9 cells, we find that the origin unwinding activities of both TS677-->A and TS677,679-->A are inhibited by the T-antigen kinase, as is wild-type T antigen. In contrast, mutants TS120-->A and TS123,679-->A are resistant to inhibition by the kinase. Thus, phosphorylation of serines 120 and 123 is necessary for inhibition of T-antigen activity. Previous studies of casein kinase I substrate specificity have suggested that acidic residues or a phosphorylated amino acid amino terminal to the target residue are required to create a casein kinase I recognition site. However, we find that the T-antigen kinase can add more than 3 mol of Pi per mol to full-length bacterially produced T antigen and that it inhibits the unwinding activity of p34cdc2-activated bacterially produced T antigen. Since no prior phosphorylation is present in this bacterially produced T antigen, and no acidic residues are present immediately amino terminal to serines 120 and 123, other structural elements of T antigen must contribute to the recognition signals for T-antigen kinase. In support of this conclusion, we find that while T-antigen kinase phosphorylates amino-terminal residues in bacterially produced full-length T antigen, it cannot phosphorylate bacterially produced truncated T antigen containing amino acids 1 to 259, a 17-kDa amino-terminal tryptic fragment of T antigen, nor can it phosphorylate denatured T antigen. These findings strongly suggest that the carboxy-terminal domain of T antigen is an important modifier of the recognition signals for phosphorylation of the critical amino-terminal sites by the T-antigen kinase. This conclusion is consistent with previous studies suggesting close apposition of amino- and carboxy-terminal domains of T antigen in the native protein. The three-dimensional conformation of the substrate appears to make a significant contribution to T-antigen kinase substrate specificity.

Isolation and characterization of the Escherichia coli htrB gene, whose product is essential for bacterial viability above 33 degrees C in rich media.

We have identified and studied the htrB gene of Escherichia coli. Insertional inactivation of the htrB gene leads to bacterial death at temperatures above 33 degrees C. The mutant bacterial phenotype at nonpermissive temperatures includes an arrest of cell division followed by the formation of bulges or filaments. The htrB+ gene has been cloned by complementation and shown to reside at 23.4 min on the E. coli genetic map, the relative order of the neighboring loci being mboA-htrB-pyrC. The htrB gene is transcribed in a counterclockwise fashion, relative to the E. coli genetic map, and its product has been identified as a membrane-associated protein of 35,000 Da. Growth experiments in minimal media indicate that the HtrB function becomes dispensable at low growth rates.

Isolation and characterization of human casein kinase I epsilon (CKI), a novel member of the CKI gene family.

The casein kinase I (CKI) gene family is a rapidly enlarging group whose members have been implicated in the control of cytoplasmic and nuclear processes, including DNA replication and repair. We report here the cloning and characterization of a novel isoform of CKI from a human placental cDNA library. The cDNA for this isoform, hCKI epsilon, predicts a basic polypeptide of 416 amino acids and a molecular mass of 47.3 kDa. It encodes a core kinase domain of 285 amino acids and a carboxyl-terminal tail of 123 amino acids. The kinase domain is 53-98% identical to the kinase domains of other CKI family members and is most closely related to the delta isoform. Localization of the hCKI epsilon gene to chromosome 22q12-13 and the hCKI delta gene to chromosome 17q25 confirms that these are distinct genes in the CKI family. Northern blot analysis shows that hCKI epsilon is expressed in multiple human cell lines. Recombinant hCKI epsilon is an active enzyme that phosphorylates known CKI substrates including a CKI-specific peptide substrate and is inhibited by CKI-7, a CKI-specific inhibitor. A budding yeast isoform of CKI, HRR25, has been implicated in DNA repair responses. Expression of hCKI epsilon but not hCKI alpha rescued the slow-growth phenotype of a Saccharomyces cerevisiae strain with a deletion of HRR25. Human CKI epsilon is a novel CKI isoform with properties that overlap those of previously described CKI isoforms.

Autoinhibition of casein kinase I epsilon (CKI epsilon) is relieved by protein phosphatases and limited proteolysis.

Casein kinase I epsilon (CKI epsilon) is a member of the CKI gene family, members of which are involved in the control of SV40 DNA replication, DNA repair, and cell metabolism. The mechanisms that regulate CKI epsilon activity and substrate specificity are not well understood. We report that CKI epsilon, which contains a highly phosphorylated 123-amino acid carboxyl-terminal extension not present in CKI alpha, is substantially less active than CKI alpha in phosphorylating a number of substrates including SV40 large T antigen and is unable to inhibit the initiation of SV40 DNA replication. Two mechanisms for the activation of CKI epsilon have been identified. First, limited tryptic digestion of CKI epsilon produces a protease-resistant amino-terminal 39-kDa core kinase with several-fold enhanced activity. Second, phosphatase treatment of CKI epsilon activates CKI epsilon 5-20-fold toward T antigen. Similar treatment of a truncated form of CKI epsilon produced only a 2-fold activation. Notably, this activation was transient; reautophosphorylation led to a rapid down-regulation of the kinase within 5 min. Phosphatase treatment also activated CKI epsilon toward the novel substrates I kappa B alpha and Ets-1. These mechanisms may serve to regulate CKI epsilon and related forms of CKI in the cell, perhaps in response to DNA damage.