Circadian and chemotherapy-related changes in urinary modified nucleosides excretion in patients with metastatic colorectal cancer.

Urinary levels of modified nucleosides reflect nucleic acids turnover and can serve as non-invasive biomarkers for monitoring tumour circadian dynamics, and treatment responses in patients with metastatic colorectal cancer. In 39 patients, median overnight urinary excretion of LC-HRMS determinations of pseudouridine, was ~ tenfold as large as those of 1-methylguanosine, 1-methyladenosine, or 4-acetylcytidine, and ~ 100-fold as large as those of adenosine and cytidine. An increase in any nucleoside excretion after chemotherapy anticipated plasma carcinoembryonic antigen progression 1-2 months later and was associated with poor survival. Ten fractionated urines were collected over 2-days in 29 patients. The median value of the rhythm-adjusted mean of urinary nucleoside excretion varied from 64.3 for pseudouridine down to 0.61 for cytidine. The rhythm amplitudes relative to the 24-h mean of 6 nucleoside excretions were associated with rest duration, supporting a tight link between nucleosides turnover and the rest-activity rhythm. Moreover, the amplitude of the 1-methylguanosine rhythm was correlated with the rest-activity dichotomy index, a significant predictor of survival outcome in prior studies. In conclusion, urinary excretion dynamics of modified nucleosides appeared useful for the characterization of the circadian control of cellular proliferation and for tracking early responses to treatments in colorectal cancer patients.

Relations between strain and gender dependencies of irinotecan toxicity and UGT1A1, CES2 and TOP1 expressions in mice.

Irinotecan hydrochloride (CPT-11) can display severe toxicities in individual cancer patients. CPT-11 is bio-activated through CES, detoxified through UGT1A1 and inhibits TOP1. CPT-11 toxicity and UGT1A1, CES2 and TOP1 mRNAs and UGT1A1 protein were determined in male and female C57BL/6, B6D2F1 and B6CBAF1, as potential models for tailoring CPT-11 delivery. CPT-11 was administered intravenously (40-90 mg/kg/day for 4 days at 7h after light onset). The relations between dose and lethal toxicity or body weight loss were steep and similar in C57BL/6 (lethality, p=0.001; weight loss, p=0.002) and B6D2F1 (p=0.01; p=0.03, respectively), but weak in B6CBAF1. Females displayed less toxicity than males (p<0.001). Mean mRNA expression of UGT1A1 was highest in B6CBAF1 (p=0.039) and in females (p<0.001). Both CES2 and TOP1 varied according to strain and gender (p<0.001). The three gene expression data explained the most severe toxicity of CPT-11 in male B6D2F1, but displayed inconsistent relations with toxicity in the other groups. Mean UGT1A1 protein expression was highest in males as compared to females, and so by approximately 8-fold in C57BL/6 as compared to B6D2F1 (p<0.0001). Genetic background and gender significantly altered the molecular prediction of irinotecan toxicity by UGT1A1, CES2 and TOP1 mRNA expressions.

Protein kinase Calpha is a calpain target in cultured embryonic muscle cells.

Previously we isolated a micro-calpain/PKCalpha complex from skeletal muscle which suggested tight interactions between the Ca2+-dependent protease and the kinase in this tissue. Our previous studies also underlined the involvement of ubiquitous calpains in muscular fusion and differentiation. In order to precise the relationships between PKCalpha and ubiquitous calpains in muscle cells, the expression of these two enzymes was first examined during myogenesis of embryonic myoblasts in culture. Our results show that calpains and PKCalpha are both present in myotubes and essentially localized in the cytosolic compartment. Moreover, calpains were mainly present after 40 h of cell differentiation concomitantly with a depletion of PKCalpha content in the particulate fraction and the appearance of PKMalpha fragment. These results suggest a possible calpain dependent down-regulation process of PKCalpha in our model at the time of intense fusion. In our experimental conditions phorbol myristate acetate (PMA) induced a rapid depletion of PKCalpha in the cytosolic fraction and its translocation toward the particulate fraction. Long term exposure of myotubes in the presence of PMA induced down-regulation of PKCalpha, this process being partially blocked by calpain inhibitors (CS peptide and inhibitor II) and antisense oligonucleotides for the two major ubiquitous calpain isoforms (m- and micro-calpains). Taken together, our findings argue for an involvement of calpains in the differentiation of embryonic myoblasts by limited proteolytic cleavage of PKCalpha.

Evidence for a MARCKS-PKCalpha complex in skeletal muscle.

MARCKS (Myristoylated Alanine Rich C Kinase Substrate) is a protein known to cross-link actin filament and consequently, is very important in the stabilization of the cytoskeletal structure. In addition, it has been recently demonstrated that the phosphorylation rate of this protein changes during myogenesis and that this protein is implicated in fusion events. For a better understanding of the biological function of MARCKS during myogenesis, we have undertaken to identify and purify this protein from rabbit skeletal muscle. Three chromatographic steps including an affinity calmodulin-agarose column were performed. The existence of a complex between the two proteins was confirmed by non-denaturing gel electrophoresis and immunoprecipitation. Two complexes were isolated which present an apparent molecular weight of about 600 kDa. Such interactions suggest that MARCKS is either a very good PKCalpha substrate and/or a regulator of PKC activity. These results are supported by previous studies showing preferential interactions and co-localization of PKC isozyme and MARCKS at focal adhesion sites. This is the first time that MARCKS has been purified from skeletal muscle and our data are consistent with a major role of this actin- and calmodulin-binding protein in cytoskeletal rearrangement or other functions mediated by PKalpha. Our results provide evidence for a tight and specific association of MARCKS and PKCalpha (a major conventional PKC isozyme in skeletal muscle) as indicated by the co-purification of the two proteins.