An endogenous F-box protein regulates ARGONAUTE1 in Arabidopsis thaliana.

ARGONAUTE1 (AGO1) mediates microRNA- and small interfering RNA-directed posttranscriptional gene silencing in Arabidopsis thaliana. Mutant alleles of SQUINT (SQN) slightly reduce AGO1 activity and have weak effects on shoot morphology. A screen for mutations that suppress the sqn phenotype produced loss-of-function mutations in the F-box gene FBW2. Mutations in FBW2 not only suppress sqn but also suppress many of the developmental phenotypes of weak, but not null, alleles of AGO1 by increasing AGO1 protein levels. Conversely, over-expression of FBW2 decreases the abundance of the AGO1 protein but not AGO1 messenger RNA, further indicating that FBW2 regulates AGO1 protein levels. fbw2 mutants have no obvious morphological phenotype, but display a reduced sensitivity to abscisic acid (ABA) that can be attributed to increased AGO1 activity. Our results indicate that FBW2 is a novel negative regulator of AGO1 and suggest that it plays a role in ABA signalling and/or response.

The SEL-12 presenilin mediates induction of the Caenorhabditis elegans uterine pi cell fate.

During Caenorhabditis elegans hermaphrodite development, the anchor cell induces the vulva and the uterine pi cells whose daughters connect to the vulva, thereby organizing the uterine-vulval connection. Both the initial selection of a single anchor cell during the anchor cell vs. ventral uterine precursor cell decision and the subsequent induction of the pi cell fate by the anchor cell are mediated by the lin-12 gene. Members of the presenilin gene family can cause early onset Alzheimer's disease when mutated and are also required for LIN-12/Notch signaling during development. We have shown that, in C. elegans, mutation of the sel-12-encoded presenilin results in pi cell induction defects. By contrast, other lin-12-mediated cell fate decisions occur normally in sel-12 mutants due to the redundant function of a second C. elegans presenilin called HOP-1. We found that the sel-12 egg-laying defect was partially rescued by expression of the sel-12 gene in the pi cells. sel-12-mediated pi cell fate specification provides a useful system for the analysis of presenilin function at single cell resolution.

Ron-mediated cytoplasmic signaling is dispensable for viability but is required to limit inflammatory responses.

Ron receptor activation induces numerous cellular responses in vitro, including proliferation, dissociation, and migration. Ron is thought to be involved in blood cell development in vivo, as well as in many aspects of the immune response including macrophage activation, antigen presentation, and nitric oxide regulation. In previous studies to determine the function of Ron in vivo, mice were generated with a targeted deletion of the extracellular and transmembrane regions of this gene. Mice homologous for this deletion appear to die early during embryonic development. To ascertain the in vivo function of Ron in more detail, we have generated mice with a germline ablation of the tyrosine kinase domain. Strikingly, our studies indicate that this domain of Ron, and therefore Ron cytoplasmic signaling, is not essential for embryonic development. While mice deficient in this domain are overtly normal, mice lacking Ron signaling have an altered ability to regulate nitric oxide levels and, in addition, have enhanced tissue damage following acute and cell-mediated inflammatory responses.

The cytoplasmic domain of C-CAM1 tumor suppressor is necessary and sufficient for suppressing the tumorigenicity of prostate cancer cells.

We have previously shown that C-CAM1 cell adhesion molecule can suppress the growth of prostate cancer cells in vivo. In this study, we determined the minimal domain of C-CAM1 that is required for its tumor-suppressive activity. DU145 prostate cancer cells were infected with recombinant adenoviruses containing various C-CAM1 mutant genes, and the effects of the mutant C-CAM1 proteins on the growth of DU145 cells were assessed in a nude-mice xenograft model. Deletion of C-CAM1's cytoplasmic domain, which is not required for its adhesion activity, abolished the growth-suppressive activity, whereas deletion of the adhesion domain did not. This observation suggests that C-CAM1's extracellular domain may be not essential for its tumor suppressive activity. Indeed, we found that expression of the C-CAM1 cytoplasmic domain alone led to growth suppression of DU145 cells. These results suggest that the cytoplasmic domain of C-CAM1 is necessary and sufficient for its growth-suppressive function.

Structural analysis of the C-CAM1 molecule for its tumor suppression function in human prostate cancer.

BACKGROUND: Recently, we demonstrated that expression of C-CAM1, an immunoglobulin (Ig)-like cell adhesion molecule (CAM), was diminished in both prostate intraepithelial neoplasia and cancer lesions, indicating that loss of C-CAM1 expression may be involved in the early events of prostate carcinogenesis. Also, increased C-CAM1 expression can effectively inhibit the growth of prostate cancer. Structurally, C-CAM1 represents a unique CAM with a potential signal transducing capability. In this study, we further analyzed the functional domain of C-CAM1 for controlling its tumor suppression function. METHODS: Recombinant adenoviruses expressing a series of C-CAM1 mutants were generated, such as AdCAMF488 (mutated C-CAM1 containing Tyr-488 --> Phe-488), AdCAMH458 (intracellular domain deletion mutant containing 458 amino acids), AdCAMG454 (intracellular domain deletion mutant containing 454 amino acids), and AdCAMDeltaD1(C-CAM1 mutant containing first Ig domain deletion). After in vitro characterization of each virus, human prostate cancer cells infected with these viruses were subcutaneously injected into athymic mouse. Both tumor incidence and volume were measured for determining the tumor suppression function for each mutant. RESULTS: In vivo tumorigenic assay indicated that AdCAMDeltaD1 without cell adhesion function still retained its tumor suppression activity. In contrast, both AdCAMH458 and AdCAMG454 decreased or lost their tumor suppression activity. CONCLUSIONS: Our data indicate that the intracellular domain of the C-CAM1 molecule is critical for inhibiting the growth of prostate cancer, suggesting that C-CAM1 interactive protein(s) may dictate prostate carcinogenesis.

Tumor-suppressive activity of CD66a in prostate cancer.

CD66a (human homolog of rat cell-cell adhesion molecule, also known as biliary glycoprotein) is a cell surface protein of the immunoglobulin family. CD66a has been shown to mediate homotypic cell adhesion. Aside from this, no other functions of this molecule have been demonstrated. We have observed previously that CD66a protein expression is lost in most prostate tumors, suggesting that the down-regulation of CD66a is associated with the abnormal growth of prostate cells. CD66a is homologous (65% identity) to rat cell-cell adhesion molecule, which has been shown to have tumor-suppressive activity. This homology suggests the possibility that CD66a might also be a tumor suppressor. In this report, we show that restoring CD66a expression in DU145 human prostate cancer cells by adenovirus (Ad)-mediated gene transfer dramatically altered the malignant phenotype of these cells, as evidenced by their reduced ability to form tumors in a xenograft animal model. This result suggests that loss of CD66a protein plays an important role in the development of prostate cancer, and that restoring CD66a expression might provide an effective treatment for prostate cancer. We further explored the possibility of using Ad vectors to deliver CD66a as a potential therapeutic agent for prostate cancer. Direct injection of Ad-CD66a, an Ad vector carrying the CD66a gene, into DU145 tumors in mice significantly suppressed the growth of these tumors. This antitumor activity of CD66a was found to be dose-dependent. These results suggest that CD66a has tumor-suppressive activity and that Ad-CD66a is a potential therapeutic agent for prostate cancer treatment.

Expression and androgen regulation of C-CAM cell adhesion molecule isoforms in rat dorsal and ventral prostate.

C-CAM is an epithelial cell adhesion molecule with two major splice variants that differ in the length of the cytoplasmic domain. C-CAM1 (long (L)-form) strongly suppresses the tumorigenicity of human prostate carcinoma cells. In contrast, C-CAM2 (short (S)-form) does not exhibit tumor-suppressive activity. In the present study we have investigated the functional significance of L-form and S-form C-CAM in rat prostate by examining their expression and distribution in different prostate lobes and their response to androgen deprivation. RNase protection assays with a probe for both C-CAM isoforms detected high levels of C-CAM messages in the rat dorso-lateral prostate (DLP). L- and S-form proteins, localized by indirect immunofluorescence using isoform-specific antipeptide antibodies, were co-expressed on the apical surface of prostate epithelial cells in normal DLP. Androgen depletion did not significantly change the steady state levels of C-CAM message and protein expression in the DLP, although there was a change in the pattern of protein expression in these lobes. In contrast, C-CAM isoform messages and proteins were undetectable in normal ventral prostate (VP) but increased markedly in this lobe in response to castration, producing isoform ratios similar to those in DLP. These results demonstrate that coordinate expression of C-CAM isoforms is maintained in the VP following androgen depletion and suggest that androgen suppresses C-CAM expression in VP but not in DLP. These results suggest that balanced expression of L- and S-form C-CAM is important for normal prostate growth and differentiation.

Demonstration of adhesion activity of the soluble Ig-domain protein C-CAM4 by attachment to the plasma membrane.

The carcinoembryonic antigen (CEA) family is a large group of proteins with immunoglobulin (Ig)-like structures. The membrane-associated CEA-family proteins have been shown to mediate intercellular adhesion. In addition to these membrane-associated proteins, several secreted CEA-like proteins, such as C-CAM4, PSG1b, and PSG11s, have also been identified. The functions of these soluble proteins are not clear because they cannot support intercellular adhesion like the membrane-associated proteins can. A fundamental question important for understanding the functions of these soluble proteins is whether they can interact in a homophilic fashion as do many of their membrane-associated homologues. We found that the homophilic interactions between these soluble proteins were too weak to be detected by solution binding assays. This is not unexpected because interactions between adhesion molecules are usually transient and weak to allow for control of association and dissociation. By expressing these soluble CEA-family proteins, C-CAM4, PSG1b, and PSG11s, as membrane-anchored forms, we showed that C-CAM4 could mediate intercellular adhesion, whereas PSG1b and PSG11s, despite their 52% identity to C-CAM4, could not. These results suggest that C-CAM4, but not PSG1b and PSG11s, can probably form homodimers. Thus, these secretory CEA-family members most likely have different interaction mechanisms, i.e., C-CAM4 might function as dimers, while PSGs might function as monomers.

Association of an 80 kDa protein with C-CAM1 cytoplasmic domain correlates with C-CAM1-mediated growth inhibition.

Decreased expression of C-CAM, a member of the CEA family of immunoglobulin like cell adhesion molecules, occurs in carcinomas of the colon, liver and prostate. Down regulation of C-CAM during the early stages of carcinogenesis in rat liver and human prostate has also been reported. We have recently shown that restoration of the expression of the isoform with long cytoplasmic domain, C-CAM1, leads to suppression of the tumorigenicity of prostatic carcinoma cells in vivo and growth suppression in vitro. These observations suggest that C-CAM1 may play an important role in regulating cell growth in normal tissues. Previous studies have demonstrated that the function of many members of the Ig-supergene family is dependent on interactions with cytoplasmic proteins. In the present study, we have used a bifunctional cross-linker to identify cellular proteins that interact directly with C-CAM1. Immunoblot analysis of WGA bound membrane proteins crosslinked with DSS identified a 180 kDa complex composed of C-CAM and an 80 kDa protein designated CAP-80 (C-CAM Associated Protein). Immunoprecipitation with anti-C-CAM antibodies showed that CAP-80 was co-precipitated with C-CAM from detergent solubilized, WGA-purified proteins. To assess the specificity of CAP-80 binding, the ability of CAP-80 to form stable complexes with C-CAM1 mutants expressed in insect cells was tested. Deletion of the cytoplasmic domain of C-CAM1 abolished complex formation whereas deletion of the extracellular Ig domains had no effect. These results suggest that a CAP-80 homologue (ICAP-80) is present in insect cells and ICAP-80 interacts with the cytoplasmic domain of C-CAM1. Replacement of Tyr488, a residue in the cytoplasmic domain known to be phosphorylated in vivo, with Phe did not diminish the association between C-CAM1 and ICAP-80, suggesting that Tyr488 phosphorylation is not required for association. The ability of various C-CAM1 mutants to associate with ICAP-80 correlated with their growth inhibitory activities, suggesting that ICAP-80/CAP-80 may play an important role in C-CAM1-mediated growth inhibition.

Suppression of tumorigenicity of breast cancer cells by an epithelial cell adhesion molecule (C-CAM1): the adhesion and growth suppression are mediated by different domains.

C-CAM1 is an epithelial adhesion molecule of immunoglobulin supergene family and has been implicated in the growth suppression of prostate cancer cells. Here we show that C-CAM1 can also suppress the tumorigenicity of breast cancer cells. These observations suggest that C-CAM1 may be a general growth suppressor in epithelial cells. In addition, we have identified the cytoplasmic domain, but not the extracellular adhesion domain, of C-CAM1 as critical for the growth suppression. Thus, the adhesion and the growth suppression functions of C-CAMI are independent of each other. Furthermore, mutation at the tyrosine phosphorylation site in the cytoplasmic domain of C-CAM1 did not obliterate C-CAM1's growth suppression function, suggesting that tyrosine phosphorylation is not involved in the signal transduction pathway leading to cell growth suppression. These studies provide the structural basis for future development of therapeutics that may selectively activate C-CAM1's growth suppression function.

Identification of a new isoform of cell-cell adhesion molecule 105 (C-CAM), C-CAM4: a secretory protein with only one Ig domain.

A series of Southern blot hybridization experiments using probes derived from different regions of the rat liver cell-cell adhesion molecule 105 (C-CAM) cDNA revealed the presence of a 9.6 kb EcoRI genomic fragment that seemed to encode a unique C-CAM isoform. An RNase protection study showed that this c-CAM transcript was expressed in placenta, spleen, lung and large intestine. In contrast, the other C-CAM isoforms, C-CAM1 and C-CAM2, are expressed in liver and small intestine. This result also suggests that the new isoform, which we named C-CAM4, was indeed encoded by a new C-CAM gene. A rat placenta cDNA library was then screened and the full-length cDNA coding for C-CAM4 was isolated. The deduced protein contained 142 amino acids and had a calculated molecular mass of 15 kDa. C-CAM4 was composed of a leader sequence and the first V-like Ig domain typical of C-CAM-family proteins. However, C-CAM4 lacked the C-like Ig domains, the transmembrane domain, and the cytoplasmic domain found in other C-CAM isoforms. Thus, C-CAM4 is different from the other known C-CAMs in that it is a secreted protein. We have previously shown that the first Ig domain of C-CAM1 is crucial for its adhesion function. The V-like Ig domain of C-CAM4 had 92% and 89% sequence identity with the corresponding regions of C-CAM1 and C-cam2 respectively. Together these results suggest that C-CAM4 may play a role in regulating the function of other C-CAM family proteins.

Functional expression of a human thrombin receptor in Sf9 insect cells: evidence for an active tethered ligand.

Desensitization of recombinant human thrombin receptors expressed in Sf9 insect cells was compared with native thrombin receptors in megakaryoblast erythroleukaemia (HEL) cells. Addition of thrombin (2 units/ml) or agonist peptide SFLLRN (10 microM) to HEL cells, or to Sf9 cells infected with recombinant baculovirus containing the thrombin receptor cDNA, produced an increase in the free cytosolic Ca2+ concentration ([Ca2+]i) as measured by fura-2. The response in HEL cells was transient, reflecting a rapid homologous desensitization. In contrast, [Ca2+]i in Sf9 cells expressing the thrombin receptor increased rapidly to a peak value that slowly declined, but remained elevated for at least 12 min following stimulation by thrombin. The sustained [Ca2+]i response to thrombin was not reversed by washout of thrombin or by any subsequent addition of hirudin. Pretreatment of Sf9 cells with either thrombin (2 units/ml) or SFLLRN (10 or 50 microM) for 5 min produced a shift in the ED50 for SFLLRN (added 10 min after washout) from 0.4 microM to 20 and 7 microM, respectively. Thus, desensitization of thrombin receptors expressed in Sf9 cells occurs slowly and reflects a decrease in receptor affinity. The sustained [Ca2+]i response in Sf9 cells stimulated by thrombin may reflect continuous activation by the tethered ligand. To test this hypothesis, the effect of protease treatment during the sustained phase of the response was examined. Addition of either aminopeptidase M or thermolysin reversed the sustained response to SFLLRN, but only thermolysin reversed the sustained response to thrombin. Thermolysin had no effect on the change in [Ca2+]i observed following carbachol stimulation of Sf9 cells expressing the M5 muscarinic receptor. Furthermore, following thermolysin treatment, the cells remained responsive to a subsequent application of SFLLRN. These results demonstrate that the tethered ligand remains active for extended periods of time after thrombin stimulation and suggests that further hydrolysis by extracellular proteases may represent an important mechanism of rapid receptor deactivation.

Structure and function of C-CAM1: effects of the cytoplasmic domain on cell aggregation.

C-CAMs are epithelial cell-adhesion molecules of the immunoglobulin supergene family with sequences highly homologous to carcinoembryonic antigen (CEA). C-CAMs and their human homologues, biliary glycoproteins, are unique among the CEA-family proteins in that they have cytoplasmic domains. Furthermore, alternative splicing generates C-CAM isoforms with different cytoplasmic domains, suggesting that the cytoplasmic domains of C-CAM may play important roles in regulating the function or functions of C-CAM. By using both sense and antisense approaches, we have shown that C-CAM1 is a tumour suppressor in prostate carcinogenesis. This observation raises the possibility that the cytoplasmic domain of C-CAM1 may be involved in signal transduction or interaction with cytoskeletal elements to elicit the tumour suppressor function. The cytoplasmic domain of C-CAM1 contains several potential phosphorylation sites, including putative consensus sequences for cyclic AMP-dependent kinase and tyrosine kinase. One of the potential tyrosine phosphorylation sites is located within the antigen-receptor homology (ARH) domain. The ARH domain of the membrane-bound IgM molecule is necessary for signal transduction in B-cells. These structural features suggest that the cytoplasmic domain of C-CAM1 may be important for signal transduction. To test this possibility, we generated several site-directed C-CAM1 mutants and tested their ability to support adhesion and their abilities to be phosphorylated in vivo. Results from these studies revealed that Tyr-488 is phosphorylated in vivo. However, replacing this tyrosine with phenylalanine did not significantly compromise its adhesion function. Similarly, Ser and Thr residues are phosphorylated in vivo, but deletion of the potential cyclic AMP-dependent kinase site did not significantly reduce the adhesion function. These results suggest that the kinase phosphorylation sites in the cytoplasmic domain of C-CAM1 are not required for the adhesion function. However, these phosphorylation sites are probably involved in the regulation of C-CAM-mediated signal transduction. Thus, there are probably distinct structural requirements for the adhesion and the signal transduction functions of C-CAM. Incidentally, a C-CAM1 deletion mutant containing a 10-amino-acid cytoplasmic domain was able to support adhesion activity. This is in contrast to our previous finding that a C-CAM isoform, C-CAM3, with a 6-amino-acid cytoplasmic domain could not support cell adhesion. This result indicates that the extra four amino acids, which are absent in C-CAM3 and contain a potential Ser/Thr phosphorylation site, are important for the adhesion function.

Structure and function of C-CAM1. The first immunoglobulin domain is required for intercellular adhesion.

Cell-CAM105 proteins (also called C-CAM) are epithelial cell adhesion molecules of the immunoglobulin (Ig) superfamily. The sequences of C-CAM are highly homologous to those of human carcinoembryonic antigen (CEA)-family proteins. In previous studies using baculoviral vectors, we showed that expression of the L-form cell-CAM105 (also called C-CAM1) in insect cells resulted in cell aggregation (Cheung, P. H., Thompson, N. L., Earley, K., Culic, O., Hixson, D., and Lin, S. H. (1993) J. Biol. Chem. 268, 6139-6146). This result indicates that the insect-cell system is suitable for studying the adhesion function of C-CAM. Since C-CAM1 contains four extracellular Ig-domains, the structural features directly responsible for C-CAM1 adhesion function were investigated by site-directed deletion and expression in the baculovirus/insect cell system. Results from these studies indicated that the first Ig domain located in the NH2-terminal of C-CAM plays a crucial role in intercellular adhesion. Site-directed deletion producing mutants lacking the second, third, or fourth Ig domains had no effect on the adhesion function. In addition, adhesion function was retained when both the third and fourth Ig domains were deleted, although the adhesion activity was reduced to half that in control cells. However, simultaneous deletion of the second, third, and fourth domains abolished adhesion, suggesting that these domains affect the accessibility of the binding site localized in the first domain. In our previous studies, we showed that the cytoplasmic domains of C-CAM play a significant role in the isoforms' adhesion activity since expression of a C-CAM isoform containing only 6 instead of 71 amino acids intracellularly failed to show the adhesion phenotype (Cheung, P. H., Culic, O., Qiu, Y., Earley, K., Thompson, N., Hixson, D. C., and Lin, S.-H. (1993) Biochem. J. 295, in press). These results together suggest that both the cytoplasmic domain and the first N-terminal Ig-like domain are required for C-CAM-mediated cell adhesion activity.

The cytoplasmic domain of C-CAM is required for C-CAM-mediated adhesion function: studies of a C-CAM transcript containing an unspliced intron.

Cell-CAM105 (also named C-CAM) is a cell surface glycoprotein involved in intercellular adhesion of rat hepatocytes. It has four extracellular immunoglobulin (Ig) domains, a transmembrane domain and a cytoplasmic domain and therefore is a member of the Ig supergene family. We have characterized multiple cDNAs of the C-CAM genes in rat intestine. Sequence analyses showed that rat intestine contained not only the previously reported L-form and S-form C-CAMs (renamed C-CAM1 and C-CAM2 respectively) but also a new isoform, C-CAM3. The C-CAM3 transcript codes for a polypeptide with a truncated C-terminus that lacks 65 amino acids from the previously reported C-CAM1 cytoplasmic domain. Unlike C-CAM1, C-CAM3 did not mediate cell adhesion when expressed in insect cells using the baculoviral expression system. Thus the extra 65 amino acids in the cytoplasmic domain of C-CAM1 are important for adhesion phenotype when expressed in insect cells. Although C-CAM1 and C-CAM2 are encoded by different genes, sequence analysis suggests that C-CAM3 is probably derived from alternative splicing of the C-CAM1 gene. To examine this possibility, we have determined the exon organization of the C-CAM1 gene. C-CAM3 differed from C-CAM1 by the presence of a single unspliced intron which contained a stop codon immediately after the regular splice junction. As a result, translation of C-CAM3 terminates at the point where C-CAM1 and C-CAM3 sequences diverge. To investigate the expression of C-CAM1, C-CAM2 and C-CAM3 in different tissues, we used an RNAase-protection assay to simultaneously assess the levels of expression of these transcripts. Using total RNA prepared from various tissues, we showed that expression of C-CAM3 was tissue-specific, and the C-CAM3 transcript accounted for about 25% of the transcripts derived from the C-CAM1 gene. However, further analysis revealed that C-CAM3 transcript was not present in cytosolic RNA, rather it was enriched in nuclear RNA prepared from hepatocytes. Although C-CAM3 cDNA contains the polyadenylation signal and is polyadenylated, these results indicate that C-CAM3 is probably an incomplete spliced product of C-CAM1 gene.

Conformation dependence of antipeptide antibodies: characterization of cell-CAM105 isoform-specific antipeptide antibodies using proteins expressed in insect cells with baculoviral vectors.

Cell-CAM105 proteins are hepatocyte adhesion molecules of the immunoglobulin superfamily. The two isoforms, L-form and S-form, are highly homologous. In their extracellular domains, only 16 amino acid substitutions are found scattered in the first immunoglobulin domain of 105 amino acids. Peptide sequences containing these differences are selected for production of antibodies. Isoform specificities of these antibodies were evaluated with proteins expressed in the baculovirus-insect cell system. In immunoblot and immunoprecipitation experiments, anti-C1 antibody, which was generated against a peptide sequence found only in the cytoplasmic domain of the L-form, reacted only with the L-form cell-CAM105 protein. Anti-N antibody, which was generated against a pentadecapeptide of the L-form, reacted with both the S- and L-isoforms. The lack of isoform specificity of anti-N is not surprising because there is only one amino acid substitution in this pentadecapeptide sequence. In contrast, S3, a S-form-specific pentadecapeptide with four amino acid substitutions was able to elicit antibody, anti-S3, specific for the S-isoform. With the commonly used immunoprecipitation procedures, only anti-C1 was able to precipitate cell-CAM105 from the liver membrane. Anti-N and anti-S3 could precipitate the proteins only after the liver membrane samples had been boiled in the presence of denaturing agents. Hydropathy analysis of these peptides revealed that both peptides N and S3 are more hydrophobic than peptide C1, suggesting that the peptide fragments N and S3 are probably not located on the surface of the protein. This may explain why boiling of the protein sample was necessary before anti-N and anti-S3 could precipitate the protein. The present study demonstrates that it is possible to produce isoform-specific antibodies for highly homologous proteins. Furthermore, we show that special sample treatment may be required to expose the antigenic sites.

Cell-CAM105 isoforms with different adhesion functions are coexpressed in adult rat tissues and during liver development.

The rat hepatocyte cell adhesion molecule cell-CAM105 has recently been shown to be composed of at least two isoforms. Expression of the two isoforms in different tissues and during fetal liver development in rats was studied by RNase protection using a probe which could specifically and simultaneously detect both isoforms. This probe revealed protected fragments of expected lengths for the L-form and the S-form in RNA samples isolated from various adult rat tissues. High levels of the L-form and S-form messages were detected in liver and intestine, moderate levels were detected in lung, and weak signals were detected in muscle, kidney, and spleen. In liver development studies, the messages for cell-CAM105 showed a major increase on the first day after birth compared to the fetal stage, and both isoform messages were proportionally increased. These results indicate that both cell-CAM105 isoforms may have function(s) related to hepatocyte differentiation. To study the adhesion function of cell-CAM105 isoforms, full-length cDNAs for these isoforms were expressed in insect cells. The insect cells expressing the L-form cell-CAM105 were found to aggregate. However, expression of S-form cell-CAM105 did not support cell aggregation. These results indicate that L-form, but not S-form, cell-CAM105 directly mediates the cell adhesion function.

DNA adducts and induction of sister chromatid exchanges in the rat following benzo[b]fluoranthene administration.

Benzo[b]fluoranthene (B[b]F) was administered (100 mg/kg by i.p. injection) to male Sprague--Dawley rats. Lungs, livers and peripheral blood lymphocytes (PBLs) were harvested 1, 3, 5, 7, 14, 28 and 56 days after treatment. Several DNA adducts were observed in each tissue, with maximal levels occurring at approximately 7 days after treatment. Lung DNA exhibited consistently higher adduct levels than liver or PBL DNA. At 56 days after B[b]F administration, the adducts in liver and PBL DNA were present at < 10 amol/microgram DNA, while in lung there were 100 amoles/microgram DNA. No significant differences were observed between tissues in the types of adducts produced. Co-chromatography with synthetic standards showed that only a minor adduct produced in vivo is derived from trans-9,10-dihydro-9,10-dihydroxybenzo[b]fluoranthene-11,12-oxide. Sister chromatid exchanges (SCEs) from whole blood cultures were significantly increased relative to concurrent controls between 1 and 14 days after B[b]F administration, with maximum levels at 14 days. By 28 days after treatment, SCEs had essentially returned to control levels. SCE induction did not correlate with the amount of B[b]F--DNA adducts remaining in the PBLs at harvest time.

DNA adducts in rat lung, liver and peripheral blood lymphocytes produced by i.p. administration of benzo[a]pyrene metabolites and derivatives.

DNA adducts produced in vivo in rat lung, liver and peripheral blood lymphocytes following the i.p. administration of several synthetic benzo[a]pyrene (B[a]P) metabolites and ring-substituted derivatives have been analyzed by the nuclease P1 version of the 32P-postlabeling assay. These include 1-, 2-, 3-, 4-, 5-, 6-, 7-, 8-, 9-, 10-, 11- and 12-hydroxy-B[a]P, (+/-)-B[a]P-trans-4,5-dihydrodiol, (+/-)-B[a]P-trans-7,8-dihydrodiol, (+/-)-B[a]P-trans-9,10-dihydrodiol and B[a]P-7,8-dione. Among the monohydroxy derivatives, only 2-, 9- and 12-hydroxy-B[a]P produced detectable adducts. The only disubstituted derivative studied that produced adducts was the trans-7,8-dihydrodiol. The resulting DNA adducts were compared to those produced in each tissue by administration of B[a]P. 9-Hydroxy-B[a]P and B[a]P-trans-7,8-dihydrodiol each lead to the formation of major B[a]P adducts seen in lung and liver respectively. None of the adducts derived from either 2-hydroxy-B[a]P or 12-hydroxy-B[a]P were observed following administration of B[a]P alone.