Enumeration of bacteriophage particles: Comparative analysis of the traditional plaque assay and real-time QPCR- and nanosight-based assays.

Bacteriophages are increasingly being utilized and considered for various practical applications, ranging from decontaminating foods and inanimate surfaces to human therapy; therefore, it is important to determine their concentrations quickly and reliably. Traditional plaque assay (PA) is the current "gold standard" for quantitating phage titers. However, it requires at least 18 h before results are obtained, and they may be significantly influenced by various factors. Therefore, two alternative assays based on the quantitative real-time polymerase chain reaction (QPCR) and NanoSight Limited (NS) technologies were recently proposed for enumerating phage particles. The present study compared the three approaches' abilities to quantitate Listeria monocytogenes-, Escherichia coli O157:H7- and Yersinia pestis-specific lytic phages quickly and reproducibly. The average coefficient of variation (CVS) of the PA method including all three phages was 0.15. The reproducibility of the PA method decreased dramatically when multiple investigators performed the assays, and mean differences of as much as 0.33 log were observed. The QPC R method required costly equipment and the synthesis of phage-specific oligonucleotide primers, but it determined phage concentrations faster (within about 4 h) and more precisely than did PA (CVS = 0.13). NS technology required costly equipment, was less precise (CVS = 0.28) than the PA and QPCR methods, and only worked when the phages were suspended in clear medium. However, it provided results within 5 min. After the overall correlation is established with the PA method, either of the two assays may be useful for quickly and reproducibly determining phage concentrations.

Reduction of pp32 expression in poorly differentiated pancreatic ductal adenocarcinomas and intraductal papillary mucinous neoplasms with moderate dysplasia.

Nuclear phosphoprotein 32 (pp32) inhibits K-ras induced transformation in experimental models. pp32 mRNA expression correlates with differentiation status in breast and prostate cancers. In this study, we evaluated pp32 protein expression in relation to the differentiation status of pancreatic ductal adenocarcinomas and precursor lesions of the pancreatic cancers. pp32 expression showed strong nuclear staining in normal pancreatic acini and ducts. The intensity of this staining was maintained in pancreatic intraepithelial neoplasia, intraductal papillary mucinous neoplasms with mild dysplasia, well-differentiated adenocarcinomas, and in a subset of moderately differentiated adenocarcinomas. pp32 staining was absent or reduced in poorly differentiated tumors and in intraductal papillary mucinous neoplasms with moderate dysplasia. We validated pp32 expression by a second technique, immunoblot analysis of lysates from resected pancreatic ductal adenocarcinomas and pancreatic cancer cell lines. The well-differentiated pancreatic cancer cell line HPAC expressed high amounts of pp32, as compared to the poorly differentiated pancreatic cancer cell lines MiaPaCa2, Pl19, and Pl21 cells. Artificial introduction of pp32 expression into a poorly differentiated cell line, MiaPaCa2, caused an increase in G1 arrest compared to control cells. On the basis of this study and previous functional work that shows pp32 can inhibit K-ras transformation, we propose that reduction in pp32 expression levels may be a critical event in the progression of pancreatic tumorigenesis in an aggressive subset of pancreatic ductal adenocarcinomas.

A pp32-retinoblastoma protein complex modulates androgen receptor-mediated transcription and associates with components of the splicing machinery.

We have previously shown pp32 and the retinoblastoma protein interact. pp32 and the retinoblastoma protein are nuclear receptor transcriptional coregulators: the retinoblastoma protein is a coactivator for androgen receptor, the major regulator of prostate cancer growth, while pp32, which is highly expressed in prostate cancer, is a corepressor of the estrogen receptor. We now show pp32 increases androgen receptor-mediated transcription and the retinoblastoma protein modulates this activity. Using affinity purification and mass spectrometry, we identify members of the pp32-retinoblastoma protein complex as PSF and nonO/p54nrb, proteins implicated in coordinate regulation of nuclear receptor-mediated transcription and splicing. We show that the pp32-retinoblastoma protein complex is modulated during TPA-induced K562 differentiation. Present evidence suggests that nuclear receptors assemble multiprotein complexes to coordinately regulate transcription and mRNA processing. Our results suggest that pp32 and the retinoblastoma protein may be part of a multiprotein complex that coordinately regulates nuclear receptor-mediated transcription and mRNA processing.

Phosphorylated retinoblastoma protein complexes with pp32 and inhibits pp32-mediated apoptosis.

The retinoblastoma gene product (Rb) is a tumor suppressor that affects apoptosis paradoxically. Most sporadic cancers inactivate Rb by preferentially targeting the pathway that regulates Rb phosphorylation, resulting in resistance to apoptosis; this contrasts with Rb inactivation by mutation, which is associated with high rates of apoptosis. How phosphorylated Rb protects cells from apoptosis is not well understood, but there is evidence that Rb may sequester a pro-apoptotic nuclear factor. pp32 (ANP32A) is a pro-apoptotic nuclear phosphoprotein, the expression of which is commonly increased in cancer. We report that hyperphosphorylated Rb interacts with pp32 but not with the closely related proteins pp32r1 and pp32r2. We further demonstrate that pp32-Rb interaction inhibits the apoptotic activity of pp32 and stimulates proliferation. These results suggest a mechanism whereby cancer cells gain both a proliferative and survival advantage when Rb is inactivated by hyperphosphorylation.

The identification of phosphorylation sites of pp32 and biochemical purification of a cellular pp32-kinase.

The versatile phosphoprotein pp32 is involved in important physiological processes, including cell proliferation, apoptosis, mRNA transport, and transcription. We have previously reported that pp32, through histone masking, inhibits histone acetylation and transcriptional activation by histone acetyltransferases. However, how pp32 itself is regulated remained largely unknown. Although pp32 is a phosphoprotein, neither the phosphorylation sites nor the cellular kinase has been identified. In this report, utilizing an in vitro kinase assay and a biochemical purification scheme, we identify casein kinase II as a cellular pp32-kinase. Our deletion and site-specific mutagenesis studies identify serines 158 and 204 as the sites of phosphorylation. Generation and utilization of antibodies with higher affinity for phospho-pp32 demonstrate that pp32 is indeed phosphorylated in vivo at these two sites. Mutagenesis studies on pp32 suggest a role for serines 158 and 204 in its function. The identification of the pp32 kinase and the sites of pp32 phosphorylation as well as the generation of antibodies with higher affinity for phospho-pp32 should now provide key information and tools for future studies on pp32 regulation.

Identification of a functional mutation in pp32r1 (ANP32C).

No mutations or polymorphisms have previously been reported in pp32r1 (ANP32C; GenBank: AF008216.1). pp32r1 is part of the highly conserved ANP32 family, some of whose members are associated with control of histone acetylation, mRNA stability, and specialized forms of apoptosis. Although 87.6% identical at the protein level, pp32r1 is functionally distinct from pp32 (ANP32A) in its failure to suppress oncogenesis in in vitro transformation systems and its tumorigenicity in in vivo assays. The present study found that pp32r1 expression levels vary among human tumor cell lines, with the highest levels found in prostatic adenocarcinoma cell lines. pp32r1 also appears to be polymorphic at nucleotide g.4520 and nucleotide g.4664 in human tobacco-associated oral mucosal lesions, human fibroblast cell lines, and several carcinoma cell lines. PC-3 human prostatic adenocarcinoma cells likewise appear to be polymorphic at these loci, but additionally contain a g.4870T>C transversion mutation. The mutation results in a p.Tyr140His substitution, which lies in a functionally important region of the molecule. In the PC-3 prostate cancer line, the mutation is either homozygous, or hemizygous accompanied by loss of heterozygosity. ACHN cells stably transfected with pp32r1 containing this mutation showed a markedly increased rate of growth. The pp32r1 mutation could thus be causally associated with the neoplastic growth properties of PC-3, and be of potential clinical significance.

pp32 reduction induces differentiation of TSU-Pr1 cells.

pp32 (ANP32A) is a nuclear phosphoprotein expressed as a nonmutated form in self-renewing cell populations and neoplastic cells. Mechanistically, pp32 may regulate pathways important in the process of differentiation as part of separate complexes inhibiting histone acetylation and regulating immediate-early and cytokine mRNA stability. Prostatic adenocarcinomas express pp32 in a differentiation related manner-well-differentiated tumors express lower levels of pp32 than poorly differentiated tumors. In benign prostate, pp32 is expressed in basal cells but not in terminally differentiated glandular cells. Based on these observations, we hypothesized that reduction of pp32 expression might be an important differentiation signal. We used anti-sense pp32 and RNAi transfection to study the effects of reduced pp32 expression in the TSU-Pr1 carcinoma cell line. pp32 reduction induced TSU-Pr1 cells to differentiate into neuronal-like cells with associated inhibition of growth. Reduction of pp32 and consequent differentiation were accompanied by a marked reduction in expression of SET, which complexes with pp32, by a marked change in acetylation status of histone H4, and by further differential expression of genes in differentiation pathways. Thus, reduction of pp32 in the undifferentiated TSU-Pr1 neoplastic cell line induces differentiation and thus may be an element of a differentiation control pathway in both normal and neoplastic cells.