Kappa free light chains is a valid tool in the diagnostics of MS: A large multicenter study.

OBJECTIVE: To validate kappa free light chain (KFLC) and lambda free light chain (LFLC) indices as a diagnostic biomarker in multiple sclerosis (MS). METHODS: We performed a multicenter study including 745 patients from 18 centers (219 controls and 526 clinically isolated syndrome (CIS)/MS patients) with a known oligoclonal IgG band (OCB) status. KFLC and LFLC were measured in paired cerebrospinal fluid (CSF) and serum samples. Gaussian mixture modeling was used to define a cut-off for KFLC and LFLC indexes. RESULTS: The cut-off for the KFLC index was 6.6 (95% confidence interval (CI) = 5.2-138.1). The cut-off for the LFLC index was 6.9 (95% CI = 4.5-22.2). For CIS/MS patients, sensitivity of the KFLC index (0.88; 95% CI = 0.85-0.90) was higher than OCB (0.82; 95%CI = 0.79-0.85; p < 0.001), but specificity (0.83; 95% CI = 0.78-0.88) was lower (OCB = 0.92; 95% CI = 0.89-0.96; p < 0.001). Both sensitivity and specificity for the LFLC index were lower than OCB. CONCLUSION: Compared with OCB, the KFLC index is more sensitive but less specific for diagnosing CIS/MS. Lacking an elevated KFLC index is more powerful for excluding MS compared with OCB but the latter is more important for ruling in a diagnosis of CIS/MS.

Biological markers in cerebrospinal fluid for axonal impairment in multiple sclerosis: acetylcholinesterase activity cannot be considered a useful biomarker.

An impairment of the cholinergic system activity has been demonstrated in multiple sclerosis (MS). The correlation between the cholinergic system and the cognitive dysfunction in MS has led to studies on the use of acetylcholinesterase inhibitors (AChEI). The acetylcholinesterase (AChE), essential enzyme for the regulation of turnover of acetylcholine, can be considered the most important biochemical indicator of cholinergic signaling in the nervous system. Besides its catalytic properties, AChE has a crucial role in the regulation of the immune function. Based on the role of the AChe in the regulation of cholinergic signaling in the nervous system, the aim of the present study is to evaluate the activity of AChE in different pathological conditions: MS, other inflammatory neurological disorders (OIND) and non-inflammatory neurological disorders (NIND). We measured AChE activity in CSF samples obtained from 34 relapsing-remitting MS patients and, as controls, 40 patients with other inflammatory neurological disorders (OIND) and 40 subjects with other non-inflammatory neurological disorders (NIND). Fluorimetric detection of the AChE in MS patients and in the controls showed no statistically significant differences: 1.507 ± 0.403 nmol/ml/min in MS patients, 1.484 ± 0.496 nmol/ml/min in OIND and 1.305 ± 0.504 nmol/ml/min in NIND. Similar results were obtained in another recent study, using a different method. Further studies must be conducted on a larger number of patients, with different degrees of cognitive impairment. However, AChE measured in CSF can probably not be considered a useful biomarker for the assessment of the functional alterations of cholinergic system in pathological conditions.

Intrathecal levels of vitamin D and IgG in multiple sclerosis.

BACKGROUND: Intrathecal synthesis of IgG is a hallmark of multiple sclerosis (MS). Vitamin D may modulate B-cell function and dampen the synthesis of IgG. OBJECTIVE: To investigate the relation between vitamin D levels in cerebrospinal fluid and serum and intrathecal synthesis of IgG. METHODS: 25-hydroxyvitamin D (25(OH)D) and IgG were assessed in cerebrospinal fluid and serum in 40 patients with MS. RESULTS: There was no significant correlation between the IgG index and 25(OH)D levels in cerebrospinal fluid or serum. The levels of 25(OH)D in cerebrospinal fluid and serum did not differ between patients with and without intrathecal synthesis of IgG. There was a non-significant trend towards a positive correlation between the concentrations of 25(OH)D and IgG in the cerebrospinal fluid, but not in serum. CONCLUSION: Physiological variation in vitamin D does not exert a major impact on intrathecal synthesis of IgG in MS.

Stepwise transformation of rat embryo fibroblasts: c-Jun, JunB, or JunD can cooperate with Ras for focus formation, but a c-Jun-containing heterodimer is required for immortalization.

Among the Jun family of transcription factors, only c-Jun displays full transforming potential in cooperation with activated c-Ha-Ras in primary rat embryo fibroblasts. c-Jun in combination with Ras can both induce foci of transformed cells from rat embryo fibroblast monolayers and promote the establishment of these foci as tumoral cell lines. JunB can also cooperate with Ras to induce foci but is unable to promote immortalization. We report here that JunD, in cooperation with Ras, induces foci with an efficiency similar to that of JunB. Artificial Jun/eb1 derivatives from each of the three Jun proteins were also analyzed. These constructs carry a heterologous homodimerization domain from the viral EB1 transcription factor and are thought to form only homodimers in the cell. We show here that these Jun/eb1 chimeras are potent transactivators of AP1 sites and that they can cooperate with c-Ha-Ras to induce foci. However, among all the Ras-Jun and Ras-Jun/eb1 combinations tested, only foci from Ras-c-Jun can be efficiently expanded and maintained as long-term growing cultures. Therefore, we suggest that a heterodimer containing c-Jun might be required for in vitro establishment of these primary mammalian cells.

Transcription factor ATF2 cooperates with v-Jun to promote growth factor-independent proliferation in vitro and tumor formation in vivo.

ATF2 belongs to the bZIP family of transcription factors and controls gene expression via 8-bp ATF/CREB motifs either as a homodimer or as a heterodimer-for instance, with Jun-but has never been shown to be directly involved in oncogenesis. Experiments were designed to evaluate a possible role of ATF2 in oncogenesis in chick embryo fibroblasts (CEFs) in the presence or absence of v-Jun. We found that (i) forced expression of ATF2 cannot alone cause transformation, (ii) overexpression of ATF2 plus v-Jun specifically stimulates v-Jun-induced growth in medium with a reduced amount of serum, and (iii) the efficiency of low-serum growth correlates with the activity of a Jun-ATF2-dependent model promoter in stably transformed CEFs. Analysis of ATF2 and Jun dimerization mutants showed that the growth-stimulatory effect of ATF2 is likely to be mediated by v-Jun-ATF2 heterodimers since (i) v-Jun-m1, a mutant with enhanced affinity for ATF2, induces growth in low-serum medium much more efficiently than v-Jun, when expressed alone or in combination with ATF2; and (ii) ATF2/fos, a mutant that efficiently binds to v-Jun but is unable to form stable homodimers, shows enhanced oncogenic cooperation with v-Jun. In addition, we examined the role of ATF2 in tumor formation by subcutaneous injection of CEFs into chickens. In contrast to v-Jun, v-Jun-m1 gave rise to numerous fibrosarcomas while coexpression of ATF2 and v-Jun-m1 led to a dramatic development of fibrosarcomas visible within 1 week. Together these data demonstrate that overexpressed ATF2 potentiates the ability of v-Jun-transformed CEFs to grow in low-serum medium in vitro and contributes to the formation of tumors in vivo.

Effects of harman and norharman on spontaneous and ultraviolet light-induced mutagenesis in cultured Chinese hamster cells.

Nontoxic concentrations of harman and norharman were tested in cultured Chinese hamster cells for their effects on DNA repair and mutagenesis. The following effects of harman were observed: (a) the survival of ultraviolet light- or X-ray-damaged cells was reduced; (b) the ultraviolet light-induced unscheduled DNA synthesis was slightly inhibited; and (c) the frequency of spontaneous or ultraviolet light-induced ouabain-resistant (ouar) or 6-thioguanine-resistant (6-TGr) mutations was reduced. Furthermore, the effect of harman on survival and mutagenesis was greater than that of norharman and was detected primarily in treatments in which cells were exposed to harman immediately following ultraviolet light irradiation. Our data clearly indicate that harman decreases the capacity to repair DNA damage and fix mutations in Chinese hamster cells, possibly because of the intercalation properties of this compound.

A congenic line of the BALB/c mouse strain with the endogenous mouse mammary tumor virus proviral gene Mtv-3: tissue-specific expression and correlation with resistance to mouse mammary tumor virus infection and tumorigenesis.

Mouse mammary tumor virus (MMTV) expression and MMTV-induced tumorigenesis were studied in a congenic line of the BALB/cHeA strain, termed BALB/c-Mtv-3+, that carries the Mtv-3 proviral gene. BALB/c-Mtv-3+ mice were free of milk-transmitted MMTV and did not spontaneously develop mammary tumors. A specific Mtv-3 expression was observed in the mammary gland and spleen, but not in other lymphoid tissues, such as thymus and bone marrow. This expression was hormone dependent, as shown by the increase of MMTV mRNA during pregnancy. At the protein level, large amounts of p28, but only traces of gp52, the main MMTV core and envelope antigens, respectively, were observed, in agreement with the already described "partial" expression of the Mtv-3 gene products. The presence of the 24S (3.8 kilobases) mRNA encoding the MMTV env antigens in the spleen and the low gp52 reactivity in lactating mammary glands showed that this noncoordinate expression was probably due to a defect in translation or posttranslational processing of env proteins. The susceptibility of BALB/c-Mtv-3+ to experimental MMTV infection was studied. The presence of Mtv-3 conferred to BALB/c mice resistance to MMTV infection, as shown by measuring viral antigens released in the milk of infected mice and by recording the incidence of early mammary tumors. The presence of a nontumorigenic endogenous MMTV gene was therefore protective against exogenous MMTV infection.

Prevalence and correlates of QTc prolongation in Italian psychiatric care: cross-sectional multicentre study.

AIMS: In recent years several warnings have been issued by regulatory authorities on the risk of electrocardiogram abnormalities in individuals exposed to psychotropic drugs. As a consequence of these warnings, monitoring of the QT interval corrected for heart rate (QTc) has become increasingly common. This study was conducted to measure the frequency of QTc prolongation in unselected psychiatric patients, and to document the associated factors using a cross-sectional approach. METHOD: The study was carried out in 35 Italian psychiatric services that are part of the STAR (Servizi Territoriali Associati per la Ricerca) Network, a research group established to produce scientific knowledge by collecting data under ordinary circumstances. During a three-month period, a consecutive unselected series of both in- and out-patients were enrolled if they performed an ECG during the recruitment period and were receiving psychotropic drugs on the day ECG was recorded. RESULTS: During the recruitment period a total of 2411 patients were included in the study. The prevalence of QTc prolongation ranged from 14.7% (men) and 18.6% (women) for the cut-off of 450 ms, to 1.26% (men) and 1.01% (women) for the cut-off of 500 ms. In the multivariate model conducted in the whole sample of patients exposed to psychotropic drugs, female sex, age, heart rate, alcohol and/or substance abuse, cardiovascular diseases and cardiovascular drug treatment, and drug overdose were significantly associated with QTc prolongation. In patients exposed to antipsychotic drugs, polypharmacy was positively associated with QTc prolongation, whereas use of aripiprazole decreased the risk. In patients exposed to antidepressant drugs, use of citalopram, citalopram dose and use of haloperidol in addition to antidepressant drugs, were all positively associated with QTc prolongation. CONCLUSIONS: The confirmation of a link between antipsychotic polypharmacy and QTc prolongation supports the current guidelines that recommend avoiding the concurrent use of two or more antipsychotic drugs, and the confirmation of a link between citalopram and QTc prolongation supports the need for routine QTc monitoring. The relatively low proportion of patients with QTc prolongation not only suggests compliance with current safety warnings issued by regulatory authorities, but also casts some doubts on the clinical relevance of QTc prolongation related to some psychotropic drugs.

Down-regulation of the extracellular matrix protein SPARC in vSrc- and vJun-transformed chick embryo fibroblasts contributes to tumor formation in vivo.

In vitro transformation of primary cultures of chick embryo fibroblasts by the membrane-bound vSrc or the nuclear vJun oncoproteins is correlated with a down-regulation of the secreted glycoprotein SPARC (also called BM-40 or osteonectin). This protein is a nonstructural component of the extracellular matrix that is thought to regulate cell-matrix interaction during development, wound repair, and carcinogenesis. Its precise function remains unclear. To estimate the contribution of SPARC down-regulation to the major aspects of the transformed phenotype, we have reexpressed this protein from a self-replicating retrovirus Rcas, designated R-SPARC, in the transformed cultures. These R-SPARC-infected cultures display the following main properties: (i) they accumulate the SPARC protein to a level identical to or only slightly higher than the level in normal chick embryo fibroblasts; (ii) they retain the main phenotypic properties characteristic of in vitro transformed cells, that is, altered morphology, capacity to grow in a reduced amount of serum, and capacity to develop colonies from single cells in agar; (iii) they display a clearly reduced capacity to develop local fibrosarcomas in vivo. Taken together, these data strongly suggest that down-regulation of SPARC contributes to the transformed phenotype triggered by vSrc and vJun in primary avian fibroblasts, by facilitating in vivo tumorigenesis.

Transcriptional control of SPARC by v-Jun and other members of the AP1 family of transcription factors.

Transformation of chick embryo fibroblasts by the v-Jun oncoprotein correlates with a down-regulation of the extracellular matrix protein SPARC and repression of the corresponding mRNA. Alteration in SPARC expression has been repeatedly reported in human cancers of various origin, and is thought to contribute to the remodeling of the extracellular matrix during neoplastic progression. Transcriptional control of SPARC is poorly understood. We show here that (i) v-Jun-mediated repression of the endogenous SPARC gene is enhanced by Fra2 but alleviated by ATF2, Fra2 and ATF2 being the two major partners of v-Jun in the transformed cells; (ii) high basal activity as well as repression by v-Jun and modulation by Fra2 and ATF2 is restricted to a small proximal fragment (-124/+16) of the chicken SPARC promoter; (iii) the activity of this minimal promoter is modulated by all the AP1 family members known in chickens (c-Jun and JunD; c-Fos and Fra2; ATF2; c-Maf, MafA, and MafB). Taken together these data demonstrate that, at least in avian primary cells, SPARC expression is under the control of the AP1 transcription factor. Further studies with the minimal (-124/+16) promoter fragment are needed to understand how this control takes place at the molecular level.

Distinct roles of Jun : Fos and Jun : ATF dimers in oncogenesis.

Jun : Fos and Jun : ATF complexes represent two classes of AP-1 dimers that (1) preferentially bind to either heptameric or octameric AP-1 binding sites, and (2) are differently regulated by cellular signaling pathways and oncogene products. To discriminate between the functions of Jun : Fos, Jun : ATF and Jun : Jun, mutants were developed that restrict the ability of Jun to dimerize either to itself, or to Fos(-like) or ATF(-like) partners. Introduction of these mutants in chicken embryo fibroblasts shows that Jun : Fra2 and Jun : ATF2 dimers play distinct, complementary roles in in vitro oncogenesis by inducing either anchorage independence or growth factor independence, respectively. v-Jun : ATF2 rather than v-Jun : Fra2 triggers the development of primary fibrosarcomas in the chicken wing. Genes encoding extracellular matrix components seem to constitute an important subset of v-Jun : ATF2-target genes. Repression of the matrix component SPARC by Jun is essential for the induction of fibrosarcomas. Avian primary cells transformed by either Jun : Fra2 or Jun : ATF2 thus provide powerful tools for the investigation of the downstream pathways involved in oncogenesis. Further genetic studies with Jun dimerization mutants will be required to be precise and extend the specific roles of the Jun : Fos and Jun : ATF dimers during cancer progression in avian and mammalian systems.

Chimeric c-Jun containing an heterologous homodimerization domain transforms primary chick embryo fibroblasts.

To investigate a possible role for c-Jun homodimers in c-Jun-mediated transformation, we designed two chimeric c-Jun derivatives, called c-Juneb1 and c-Jungcn4. In these chimeric derivatives the natural dimerization domain of c-Jun was replaced by the heterologous homodimerization domain of the Epstein-Barr virus EB1 or the yeast GCN4 transcription factor. Chick embryo fibroblasts chronically infected with retroviruses expressing c-Jun, c-Juneb1 or c-Jungcn4 are transformed. Infection with each construction results in sustained growth in low serum and development of colonies from single cells in agar with similar efficiencies. In contrast to c-Jun, c-Juneb1 and c-Jungcn4 confer additional phenotypic alterations related to in vitro transformation including a condensed cell morphology and ability to develop highly invasive, fast growing colonies in agar. These data suggest that c-Jun homodimers can transform chick embryo fibroblasts and activate cellular functions which influence cell morphology and invasive potential in agar. These findings are consistent with the notion that cellular transformation by c-jun is mediated by c-Jun homodimers.

Transcription factor ATF3 partially transforms chick embryo fibroblasts by promoting growth factor-independent proliferation.

Activating Transcription Factor 3 (ATF3) is a member of the bZip family of transcription factors. Previous studies in mammalian cells suggested that like other bZip family members e.g. Jun and Fos, ATF3 might play a role in the control of cell proliferation and participate in oncogenic transformation. To investigate this putative ATF3 function directly, the rat ATF3 protein was compared with v-Jun for its ability to transform primary cultures of chick embryo fibroblasts (CEFs). Like CEFs accumulating v-Jun, CEFs accumulating the ATF3 protein displayed a typical, fusiform morphology, associated with an enhanced capacity to grow in medium with reduced amount of serum. However, in contrast to v-Jun-transformed CEFs, the ATF3 overexpressing cells could not promote colony formation from single cells in agar. Partial transformation induced by ATF3 was found to be associated with repression of multiple cellular genes that are also down-regulated by v-Jun, including those coding for the extracellular components fibronectin, decorin, thrombospondin 2, and the pro-apoptotic protein Par-4. These data demonstrate that, at least in primary avian cells, rat ATF3 possesses an intrinsic oncogenic potential. Moreover, the results suggest that ATF3 might induce growth factor independence by down-regulating a subset of the genes repressed by v-Jun.

In vitro transforming capacities of mouse c-jun:junD chimeric genes.

Among the murine Jun family of transcription factors, c-Jun and JunD are closely-related proteins with similar dimerization, DNA binding and transactivating properties. However, when expressed from a self-replicating retroviral RCAS vector, c-jun, but not junD, transforms chick embryo fibroblasts. We attempted to map the regions of c-jun which are important for transformation by constructing hybrids between c-jun and junD. Using common restriction sites, we prepared six different chimeric molecules. All of these c-jun:junD hybrids code for transactivators of AP1-containing promoters. An N-terminal segment of 79 amino acids of c-Jun converts JunD into a strong transforming protein, while other segments of c-Jun contribute to a lesser extent. Contrary to what has been reported with rat embryo fibroblasts, a c-Jun derivative with serines substituted by alanines in positions 63 and 73 still transforms CEFs efficiently.

Increased transforming activity of JunB and JunD by introduction of an heterologous homodimerization domain.

The closely-related proteins c-Jun, JunB and JunD form a family of transcription factors which require dimerization for DNA-binding and transcriptional activity. Dimerization is mediated by a conserved amphipathic alpha-helix located adjacent to a highly charged DNA-binding domain. The Jun proteins can form both homo- and heterodimers within the Jun family and can also cross-dimerize with the Fos proteins. When expressed at high levels in primary chicken cells, each mouse Jun displays distinct transforming capacities: c-Jun transforms efficiently, JunB transforms poorly, and JunD does not transform at all. The composition of the transforming dimers, however, is unknown. To study the activity of Jun-Jun homodimers we constructed artificial derivatives, denoted Juneb1, in which the naturally occurring dimerization domain has been replaced by an heterologous homodimerization domain from the Epstein-Barr virus transcription factor EB1. These derivatives were introduced into chicken cells and assayed for their ability to affect growth. Unexpectedly, all three Juneb1 proteins conferred a transformed phenotype to primary cultures, promoting sustained growth in low-serum medium and colony formation from single cells in agar. These data demonstrate that when forced to accumulate as homodimers, both JunB and JunD can transform cells. They also suggest that the poor transforming activity of JunB and the absence of transforming activity of JunD may be due to their inability to accumulate to high levels as homodimers.

Overexpression of avian or mouse c-jun in primary chick embryo fibroblasts confers a partially transformed phenotype.

The coding sequences of avian (quail) or murine c-jun proto-oncogenes were introduced into a non-defective retroviral vector derived from Rous sarcoma virus (RSV) in which c-jun replaces v-src. Primary avian fibroblasts chronically infected with either one of these viruses exhibit some phenotypic traits characteristic of RSV-transformed cells, including sustained growth in low serum medium and ability to develop colonies from single cells in agar, even though they are still of normal morphology and contact inhibited. This altered growth control correlates with enhanced AP1-specific DNA binding activity as well as with higher levels of c-Jun products. Unexpectedly, repression of the endogenous c-Jun product is observed in cells overexpressing murine c-Jun. Cells expressing the avian and the murine c-Jun products display qualitatively similar phenotypes; nevertheless, for every transformed trait considered, the murine c-jun seemed more potent than its quail homologue. These data suggest that the avian or murine c-jun proto-oncogenes may trigger a subset of the 'transforming functions' normally induced by v-src, and which are more specifically related to growth in low serum and in the absence of solid support.

Tumor induction by v-Jun homodimers in chickens.

To study the contribution of v-Jun homodimers to oncogenesis, we constructed artificial v-Jun derivatives in which the natural dimerization domain of v-Jun was replaced by an heterologous homodimerization domain from either the viral EB1 or the yeast GCN4 transcription factor. The resulting v-Jun chimeric proteins, called v-Juneb1 and v-Jungcn4, which can no longer dimerize with Jun or Fos, should only form homodimers in the cell. Helper-independent retroviruses expressing v-Jun, v-Juneb1 and v-Jungcn4 were generated. All three viruses transformed primary cultures of chick embryo cells with the same high efficiency and promoted local tumor growth after subcutaneous injection of infected cells in young animals. In contrast, after intravenous injection of viral suspensions into chick embryos, only the chimeric proteins produced internal tumors that were lethal. These tumors were leiomyosarcomas located within the liver and along the digestive tract. Thus, in vivo, v-Juneb1 and v-Jungcn4 are more potent oncoproteins than v-Jun. These data demonstrate that when forced to accumulate, v-Jun homodimers can induce tumors efficiently. They also show that the oncogenic potential of v-Jun can be regulated through the properties of its dimerization domain.

The defective transforming phenotype of c-Jun Ala(63/73) is rescued by mutation of the C-terminal phosphorylation site.

Cotransfection of primary rat embryo fibroblasts (REF) with c-Jun and activated Ras leads to oncogenic transformation and this process requires the phosphorylation of the N-terminal domain of c-Jun. Ras augments this phosphorylation and, consequently activates the c-Jun transactivation property of TRE (TPA Responsive Element)-dependent promoters. To analyse the role of the c-Jun C-terminal phosphorylation site in oncogenic cooperation we tested the activities of N-terminal c-Jun Ala(63/73) (named Nt), C-terminal c-Jun Ala(234/242/246/252) (named Ct) and (Nt+Ct)-with both mutations-non-phosphorylatable c-Jun mutants. In cooperation with Ras, the Ct mutant and wt c-Jun display similar oncogenic properties whereas the Nt form was defective in transforming REF cells. Unexpectedly, the Nt+Ct mutant exhibited identical oncogenic properties to wt c-Jun, demonstrating that the Ct mutation rescues in cis the Nt mutation. The transcriptional activity and the capacity to bind the c-Jun coactivator CREB Binding Protein (CBP) were enhanced by Ras for the wt and Ct proteins but not for the Nt mutant. Interestingly, the Nt+Ct mutant presents identical transactivation and CBP binding activities to wt c-Jun. Therefore the rescue in cis of the defective Nt mutation by the Ct mutation seems to be due to the recovery of CBP binding. Our results revealed that the process of oncogenic cooperation can occur between Ras and the Nt+Ct non-phosphorylatable c-Jun protein.

Opposing functions of ATF2 and Fos-like transcription factors in c-Jun-mediated myogenin expression and terminal differentiation of avian myoblasts.

With the aim to identify the oncoprotein partners implicated in the c-Jun myogenic influence, we carried out stable transfection experiments of c-Jun and/or ATF2, Fra2, c-Fos overexpression in avian myoblasts. Before induction of differentiation, c-Jun repressed myoblast withdrawal from the cell cycle, as did a TPA treatment. However, after serum removal, unlike TPA, c-Jun significantly stimulated myoblast differentiation. In search for specific partners involved in this dual influence, we found that a reduction in the amounts of c-Fos and Fra2 and an increase in c-Jun proteins occurred at cell confluence, a situation likely to favor cooperation between c-Jun and ATF2 during terminal differentiation. Whereas c-Fos and Fra2 cooperated with c-Jun to abrogate myoblast withdrawal from the cell cycle and terminal differentiation, ATF2 co-expression potentiated the positive myogenic c-Jun influence. In addition, myogenin expression was a positive target of this cooperation and this regulation occurred through a stimulation of myogenin promoter activity: (1) whereas c-Fos or Fra2 co-expression abrogated c-Jun stimulatory activity on this promoter, ATF2 co-expression potentiated this influence; (2) using a dominant negative ATF2 mutant, we established that c-Jun transcriptional activity required functionality of endogenous ATF2. These data suggest that through this dual myogenic influence due to cooperations with different partners, c-Jun is involved in the control of duration of myoblast proliferation and thereafter of fusion efficiency.

A colorimetric assay for serial determination of adenosine deaminase activity in small lymphocyte populations.

We describe here an easy, sensitive and quantitative assay for the determination of adenosine deaminase activity in small populations of lymphoid cells. Determinations of enzyme activity and protein concentration are based on colorimetric reactions. All steps are directly performed in 96-well flat-bottom microtiter plates: growth of lymphoid cells (1-2 X 10(5) cells needed), detergent-mediated lysis, incubations for enzymatic assay, and reading of colorimetric reactions with an automatic multiscan spectrophotometer. Thus, screening of several hundred independent cell cultures is easily done within a day. Applications to the detection of rare adenosine deaminase variants from large cell populations and to routine medical assays are considered.