Prostate Transglutaminase (TGase-4) Induces Epithelial-to-Mesenchymal Transition in Prostate Cancer Cells.

More men die with prostate cancer (PCa) than from it. However, once PCa is no longer organ-confined, it is associated with significant mortality. Epithelial-to-mesenchymal transition (EMT) is one mechanism facilitating progression in cancer. Our studies of transglutaminase-4 (TGase-4), a member of the TGase family, expressed in the prostate gland, have implicated it in the regulation of the invasive properties of PCa. The present study investigated the role of TGase-4 on EMT of PCa cells. MATERIALS AND METHODS: A panel of PCa cell lines: CA-HPV-10, PZ-HPV-7, PC-3 and DU-145 were used. An anti-TGase-4 transgene was constructed to eliminate the expression of TGase-4 in CA-HPV-10 (positive for TGase-4). An expression construct for human TGase-4 was used to transfect PCa cells negative for TGase-4. The pattern of E-cadherin, N-cadherin and vimentin in these cells were evaluated using immunofluorescent staining. Cell motility was assessed using scratch wounding and ekectric cell-substrate impedance sensing (ECIS) assays. RESULTS: Treatment of PZ-HPV-7 and CA-HPV-10 cells with rhTGase-4 resulted in a significant increase in cell migration (1,407.9 Ω±6.4 Ω vs. 1,691.2 Ω±8.3 Ω in non-treated and rhTGase-4 treated cells, respectively, p<0.01). Cells strongly expressing E-cadherin showed substantial changes of E-cadherin staining in that, after treatment with TGase-4, the intercellular staining of E-cadherin was diminished. Concomitantly, there was acquisition of N-cadherin in TGase-4-treated cells. Elimination of TGase-4 from CA-HPV-10 cells significantly decreased cell motility (128.1 Ω±107.4 Ω vs. 31.7 Ω±26.2 Ω, in CA-HPV-10 control and CA-HPV-10/TGase-4 knockout cells). Knocking- out TGase-4 from CA-HPV-10 cells also resulted in substantial loss of N-cadherin in the cells. CONCLUSION: TGase-4 resulted in loss of E-cadherin/acquisition of N-cadherin and cell migration indicating it is a keen regulator of EMT in prostate epithelia-derived cancer cells. In concert with its other properties involved in disease progression, the present observations suggest TGase-4 as a prospective marker of disease progression.

Fluoroquinolone-related neuropsychiatric and mitochondrial toxicity: a collaborative investigation by scientists and members of a social network.

BACKGROUND: The 3 fluoroquinolone (FQ) antibiotics - ciprofoxacin, levofoxacin, and moxifoxacin - are commonly administered to oncology patients. Although these oral antibiotics are approved by the US Food and Drug Administration (FDA) for treatment of urinary tract infections, acute bacterial sinusitis, or bacterial infection in patients with chronic obstructive pulmonary disease, they are commonly prescribed off-label to neutropenic cancer patients for the prevention and treatment of infections associated with febrile neutropenia. New serious FQ-associated safety concerns have been identified through novel collaborations between FQ-treated persons who have developed long-term neuropsychiatric (NP) toxicity, pharmacovigilance experts, and basic scientists. OBJECTIVE: To conduct basic science and clinical investigations of a newly identified adverse drug reaction, termed FQ-associated disability. METHODS: 5 groups of C57BL/6 mice receiving the antibiotic ciprofoxacin in 10-mg increments (10 mg/kg-50 mg/kg) and 1 group of control mice were evaluated. The Southern Network on Adverse Reactions (SONAR) and a social network of FQ-treated persons with long-term NP toxicity (the Floxed Network) conducted a web-based survey. The clinical toxicity manifestations reported by 94 respondents to the web-based survey of persons who had received 1 or more doses of an FQ prescribed for any indication (generally at FDA-approved dosages) and who subsequently experienced possible adverse drug reactions were compared with adverse event information included on the product label for levofoxacin and with FQ-associated adverse events reported to the FDA's MedWatch program. RESULTS: Mice treated with ciprofoxacin had lower grip strengths, reduced balance, and depressive behavior compared with the controls. For the survey, 93 of 94 respondents reported FQ-associated events including anxiety, depression, insomnia, panic attacks, clouded thinking, depersonalization, suicidal thoughts, psychosis, nightmares, and impaired memory beginning within days of FQ initiation or days to months of FQ discontinuation. The FDA Adverse Event Reporting System (FAERS) included 210,705 adverse events and 2,991 fatalities for FQs. Levofoxacin and ciprofoxacin toxicities were neurologic (30% and 26%, respectively), tendon damage (8% and 6%), and psychiatric (10% and 2%). In 2013, an FDA safety review reported that FQs affect mammalian topoisomerase II, especially in mitochondria. In 2013 and 2014, SONAR fled citizen petitions requesting black box revisions identifying neuropsychiatric toxicities and mitochrondrial toxicity as serious levofoxacin-associated adverse drug reactions. In 2015, FDA advisors recommended that FQ product labels be revised to include information about this newly identified disability syndrome termed "FQ-associated disability" (FQAD). LIMITATIONS: Basic science studies evaluated NP toxicity for only 1 FQ, ciprofoxacin. CONCLUSION: Pharmacovigilance investigators, a social network, and basic scientists can collaborate on pharmacovigilance investigations. Revised product labels describing a new serious adverse drug reaction, levofoxacin-associated long-term disability, as recommended by an FDA advisory committee, are advised.

Regulatory and clinical considerations for biosimilar oncology drugs.

Biological oncology products are integral to cancer treatment, but their high costs pose challenges to patients, families, providers, and insurers. The introduction of biosimilar agents-molecules that are similar in structure, function, activity, immunogenicity, and safety to the original biological drugs-provide opportunities both to improve health-care access and outcomes, and to reduce costs. Several international regulatory pathways have been developed to expedite entry of biosimilars into global marketplaces. The first wave of oncology biosimilar use was in Europe and India in 2007. Oncology biosimilars are now widely marketed in several countries in Europe, and in Australia, Japan, China, Russia, India, and South Korea. Their use is emerging worldwide, with the notable exception of the USA, where several regulatory and cost barriers to biosimilar approval exist. In this Review, we discuss oncology biosimilars and summarise their regulatory frameworks, clinical experiences, and safety concerns.

Prostate transglutaminase (TGase-4, TGaseP) enhances the adhesion of prostate cancer cells to extracellular matrix, the potential role of TGase-core domain.

BACKGROUND: Transglutaminase-4 (TGase-4), also known as the Prostate Transglutaminase, is an enzyme found to be expressed predominately in the prostate gland. The protein has been recently reported to influence the migration and invasiveness of prostate cancer cells. The present study aimed to investigate the influence of TGase-4 on cell-matrix adhesion and search for the candidate active domain[s] within the protein. METHODS: Human prostate cancer cell lines and prostate tissues were used. Plasmids that encoded different domains and full length of TGase-4 were constructed and used to generate sublines that expressed different domains. The impact of TGase-4 on in vitro cell-matrix adhesion, cell migration, growth and in vivo growth were investigated. Interactions between TGase-4 and focal adhesion complex proteins were investigated using immunoprecipitation, immunofluorescence and phosphospecific antibodies. RESULTS: TGase-4 markedly increased cell-matrix adhesion and cellular migration, and resulted in a rapid growth of prostate tumours in vivo. This effect resided in the Core-domain of the TGase-4 protein. TGase-4 was found to co-precipitate and co-localise with focal adhesion kinase (FAK) and paxillin, in cells, human prostate tissues and tumour xenografts. FAK small inhibitor was able to block the action mediated by TGase-4 and TGase-4 core domain. CONCLUSION: TGase-4 is an important regulator of cell-matrix adhesion of prostate cancer cells. This effect is predominately mediated by its core domain and requires the participation of focal adhesion complex proteins.

Cell-based therapy for epithelial wounds.

BACKGROUND AIMS: Bone marrow-derived cells (BMDC) form a significant portion of regenerating epithelial tissue. The purpose of this study was to determine whether exogenous BMDC (containing stroma, stem and progenitor cells), introduced systemically or within the injury site, could enhance the injury repair response. METHODS: Excisional wounds (10-mm diameter) were treated by systemic (intravenous; i.v.) and local (subcutaneous; s.c.) administration of BMDC (10-20 × 10(6)/100 µL phosphate-buffered saline). Young and aged BMDC and recipients were studied. RESULTS: Young BMDC (2 months old) increased the healing rate compared with older BMDC (1 year old), as measured by the rate of healing and the percentage of healed tissue. Young recipients had statistically better healing efficiency than older recipients. When old BMDC were used, young recipients had a better healing ability than older recipients. In addition, when the size of the healed tissue, the area of repigmentation and hair growth at the injury site were compared, young BMDC and young recipients had superior effects compared with old BMDC and old recipients. CONCLUSIONS: These results demonstrate that cellular therapy is important for wound healing in older recipients that do not heal significantly without intervention. BMDC injections result in normal healing, indistinguishable from young recipients. Significantly, a single injection into the wound margin is sufficient to reverse the wounding process and promote normal wound healing. Although younger recipients eventually healed without therapy, BMDC injections accelerated the process, reduced scarring and increased hair regrowth. These findings provide insight into the treatment of non-healing epithelial tissue with BMDC.

Prostate-specific antigen testing across the spectrum of prostate cancer.

Prostate-specific antigen (PSA) is a protein produced by the prostate, and this protein may be elevated for several reasons, including prostatitis, benign prostatic hypertrophy and/or cancer. PSA is not cancer-specific, cannot be used as a cancer marker and it has been demonstrated that there is no level of PSA that is definitive for prostate cancer. The value of the PSA test varies when used for screening, diagnosis, prognosis or as a signal of disease recurrence. Misuse of the test for screening has created unnecessary anxiety and costs, and has led to the significant overdiagnosis and overtreatment of men. More important than whether or not to screen is how one acts upon the data from a single test; with the exception of extremely high double- or triple-digit levels of PSA, it is prudent only to use a single PSA determination as a baseline, with biopsy and cancer treatment reserved for those with significant PSA changes over time, or for those with clinical manifestations mandating immediate therapy. Using the PSA test to monitor disease progression or recurrence is appropriate, provided one understands that absolute levels of PSA are rarely meaningful; it is the relative change in PSA levels over time that provides insight, but not definitive proof of a cancerous condition necessitating therapy. PSA secretion is under hormonal control and thus PSA levels may be affected differently by the type of drug therapy, by the stage of a patients' disease, and by genetic factors suggesting some men are 'high PSA producers'. Until a validated alternative test for prostate cancer is found and adopted, the current flawed PSA test needs to be used more judiciously and not used for routine screening as studies have demonstrated that screening, as defined, does not lead to a reduction in patient mortality. All men, their families and their physicians need to understand the significant limitations of PSA testing.

Prostate transglutaminase: a unique transglutaminase and its role in prostate cancer.

Prostate transglutaminase-4, also known as TGM4 or transglutaminase P, belongs to the prostate transglutaminase protein family, but is almost uniquely distributed in the prostate gland. Recent years have seen an expansion of interest in this enzyme, which is intriguingly expressed in prostate tissues and prostate cancer. In recent studies, the molecule has been found to have a diverse impact on prostate cancer cell growth, migration and invasiveness, and to be involved in the tumor-endothelial interaction and epithelial-mesenchymal transition, and has a wide interaction with other molecular complexes implicating it as a possible biomarker of aggressive versus nonaggressive cancer, as well as a therapeutic factor. This article reviews the recent progress and discusses the controversies and future directions in this exciting area of prostate cancer research.

Prostate transglutaminase (TGase-4) antagonizes the anti-tumour action of MDA-7/IL-24 in prostate cancer.

BACKGROUND: Transglutamiase-4 (TGase-4), also known as prostate transglutaminase, belongs to the TGase family and is uniquely expressed in the prostate gland. The functions of this interesting protein are not clearly defined. In the present study, we have investigated an unexpected link between TGase-4 and the melanoma differentiation-associated gene-7/interleukin-24 (MDA-7/IL-24), a cytokine known to regulate the growth and apoptosis of certain cancer and immune cells. METHODS: Frozen sections of normal and malignant human prostate tissues and human prostate cancer (PCa) cell lines PC-3 and CA-HPV-10, cell lines expressing low and high levels of TGase-4, and recombinant MDA-7/IL-24 (rhMDA-7/IL-24) were used. Expression construct for human TGase-4 was generated using a mammalian expression vector with full length human TGase-4 isolated from normal human prostate tissues. PC-3 cells were transfected with expression construct or control plasmid. Stably transfected cells for control transfection and TGase-4 over expression were created. Similarly, expression of TGase-4 in CA-HPV-10 cells were knocked down by way of ribozyme transgenes. Single and double immunofluorescence microscopy was used for localization and co-localization of TGase-4 and MDA-7/IL-24 in PCa tissues and cells with antibodies to TGase-4; MDA-7/IL-24; IL-20alpha; IL-20beta and IL-22R. Cell-matrix adhesion, attachment and migration were by electric cell substrate impedance sensing and growth by in vitro cell growth assay. A panel of small molecule inhibitors, including Akt, was used to determine signal pathways involving TGase-4 and MDA-7/IL-24. RESULTS: We initially noted that MDA-7 resulted in inhibition of cell adhesion, growth and migration of human PCa PC-3 cells which did not express TGase-4. However, after the cells over-expressed TGase-4 by way of transfection, the TGase-4 expressing cells lost their adhesion, growth and migratory inhibitory response to MDA-7. On the other hand, CA-HPV-10 cells, a cell type naturally expressing high levels of TGase-4, had a contrasting response to MDA-7 when compared with PC-3 cells. Inhibitor to Akt reversed the inhibitory effect of MDA-7, only in PC-3 control cells, but not the TGase-4 expressing PC-3 cells. In human prostate tissues, TGase-4 was found to have a good degree of co-localization with one of the MDA-7 receptor complexes, IL-20Ra. CONCLUSION: The presence of TGase-4 has a biological impact on a prostate cancer cell's response to MDA-7. TGase-4, via mechanism(s) yet to be identified, blocked the action of MDA-7 in prostate cancer cells. This has an important implication when considering the use of MDA-7 as a potential anticancer cytokine in prostate cancer therapies.

Cancer metastasis, challenges, progress and the opportunities.

The spread of cancer cells in the body -'metastasis,' is a challenging issue for cancer patients and for cancer research. From a clinical point of view, the majority of the cancer-related deaths in patients who suffer from solid cancers are metastasis-related. Although this life threatening consequence in cancer is recognised almost immediately at the time of diagnosis, the current-state-of-knowledge on the mechanisms and effective ways to combat cancer metastasis in clinical settings is far from being realized. Thus, making the necessity of continuing research into cancer metastasis evermore demanding and critical. This issue of the journal is directed toward consideration of some of the salient aspects of cancer metastasis, with a focus on recent progress of the molecular and cellular mechanisms of cancer invasion and metastasis.