Characterizing the Cellular Response to Nitrogen-Doped Carbon Nanocups

Carbon nanomaterials, specifically, carbon nanotubes (CNTs) have many potential applications in biology and medicine. Currently, this material has not reached its full potential for application due to the potential toxicity to mammalian cells, and the incomplete understanding of how CNTs interface with cells. The chemical composition and structural features of CNTs have been shown to directly affect their biological compatibility. The incorporation of nitrogen dopants to the graphitic lattice of CNTs results in a unique cup shaped morphology and minimal cytotoxicity in comparison to its undoped counterpart. In this study, we investigate how uniquely shaped nitrogen-doped carbon nanocups (NCNCs) interface with HeLa cells, a cervical cancer epithelial cultured cell line, and RPE-1 cells, an immortalized cultured epithelial cell line. We determined that NCNCs do not elicit a cytotoxic response in cells, and that they are uptaken via endocytosis. We have conjugated fluorescently tagged antibodies to NCNCs and shown that the protein-conjugated material is also capable of entering cells. This primes NCNCs to be a good candidate for subsequent protein modifications and applications in biological systems.

Cell division patterns and chromosomal segregation defects in oral cancer stem cells

Oral squamous cell carcinoma (OSCC) is a serious public health problem caused primarily by smoking and alcohol consumption or human papillomavirus. The cancer stem cell (CSC) theory posits that CSCs show unique characteristics, including self-renewal and therapeutic resistance. Examining biomarkers and other features of CSCs is critical to better understanding their biology. To this end, the results show that cellular SOX2 immunostaining correlates with other CSC biomarkers in OSCC cell lines and marks the rare CSC population. To assess whether CSC division patterns are symmetrical, resulting in two CSC, or asymmetrical, leading to one CSC and one cancer cell, cell size and fluorescence intensity of mitotic cells stained with SOX2 were analyzed. Asymmetrical SOX2 distribution in ≈25% of the mitoses analyzed was detected. Chromosomal instability, some of which is caused by chromosome segregation defects (CSDs), is a feature of cancer cells that leads to altered gene copy numbers. We compare chromosomal instability (as measured by CSDs) between CSCs (SOX2+) and non-CSCs (SOX2-) from the same OSCC cell lines. CSDs were more common in non-CSCs (SOX2-) than CSCs (SOX2+) and in symmetrical CSC (SOX2+) mitotic pairs than asymmetrical CSC (SOX2+/SOX2-) mitotic pairs. CSCs showed fewer and different types of CSDs after ionizing radiation treatment than non-CSCs. Overall, these data are the first to demonstrate both symmetrical and asymmetrical cell divisions with CSDs in OSCC CSC. Further, the results suggest that CSCs may undergo altered behavior, including therapeutic resistance as a result of chromosomal instability due to chromosome segregation defects. © 2016 Wiley Periodicals, Inc.

Targeted inhibition of ATR or CHEK1 reverses radioresistance in oral squamous cell carcinoma cells with distal chromosome arm 11q loss

Oral squamous cell carcinoma (OSCC), a subset of head and neck squamous cell carcinoma (HNSCC), is the eighth most common cancer in the U.S.. Amplification of chromosomal band 11q13 and its association with poor prognosis has been well established in OSCC. The first step in the breakage-fusion-bridge (BFB) cycle leading to 11q13 amplification involves breakage and loss of distal 11q. Distal 11q loss marked by copy number loss of the ATM gene is observed in 25% of all Cancer Genome Atlas (TCGA) tumors, including 48% of HNSCC. We showed previously that copy number loss of distal 11q is associated with decreased sensitivity (increased resistance) to ionizing radiation (IR) in OSCC cell lines. We hypothesized that this radioresistance phenotype associated with ATM copy number loss results from upregulation of the compensatory ATR-CHEK1 pathway, and that knocking down the ATR-CHEK1 pathway increases the sensitivity to IR of OSCC cells with distal 11q loss. Clonogenic survival assays confirmed the association between reduced sensitivity to IR in OSCC cell lines and distal 11q loss. Gene and protein expression studies revealed upregulation of the ATR-CHEK1 pathway and flow cytometry showed G2 M checkpoint arrest after IR treatment of cell lines with distal 11q loss. Targeted knockdown of the ATR-CHEK1 pathway using CHEK1 or ATR siRNA or a CHEK1 small molecule inhibitor (SMI, PF-00477736) resulted in increased sensitivity of the tumor cells to IR. Our results suggest that distal 11q loss is a useful biomarker in OSCC for radioresistance that can be reversed by ATR-CHEK1 pathway inhibition.

Kinesin molecular motor Eg5 functions during polypeptide synthesis

The microtubule motor Eg5 is well known for its functions during mitosis. It is shown that during interphase, Eg5 associates with ribosomes and is required for efficient protein synthesis.

The kinesin-related molecular motor Eg5 plays roles in cell division, promoting spindle assembly. We show that during interphase Eg5 is associated with ribosomes and is required for optimal nascent polypeptide synthesis. When Eg5 was inhibited, ribosomes no longer bound to microtubules in vitro, ribosome transit rates slowed, and polysomes accumulated in intact cells, suggesting defects in elongation or termination during polypeptide synthesis. These results demonstrate that the molecular motor Eg5 associates with ribosomes and enhances the efficiency of translation.

The c-Myc target glycoprotein1balpha links cytokinesis failure to oncogenic signal transduction pathways in cultured human cells

An increase in chromosome number, or polyploidization, is associated with a variety of biological changes including breeding of cereal crops and flowers, terminal differentiation of specialized cells such as megakaryocytes, cellular stress and oncogenic transformation. Yet it remains unclear how cells tolerate the major changes in gene expression, chromatin organization and chromosome segregation that invariably accompany polyploidization. We show here that cancer cells can initiate increases in chromosome number by inhibiting cell division through activation of glycoprotein1b alpha (GpIbalpha), a component of the c-Myc signaling pathway. We are able to recapitulate cytokinesis failure in primary cells by overexpression of GpIbalpha in a p53-deficient background. GpIbalpha was found to localize to the cleavage furrow by microscopy analysis and, when overexpressed, to interfere with assembly of the cellular cortical contraction apparatus and normal division. These results indicate that cytokinesis failure and tetraploidy in cancer cells are directly linked to cellular hyperproliferation via c-Myc induced overexpression of GpIbalpha.

Deficiency in myosin light-chain phosphorylation causes cytokinesis failure and multipolarity in cancer cells

Cancer cells often have unstable genomes and increased centrosome and chromosome numbers, which are an important part of malignant transformation in the most recent model of tumorigenesis. However, very little is known about divisional failures in cancer cells that may lead to chromosomal and centrosomal amplifications. In this study, we show that cancer cells often failed at cytokinesis because of decreased phosphorylation of the myosin regulatory light chain (MLC), a key regulatory component of cortical contraction during division. Reduced MLC phosphorylation was associated with high expression of myosin phosphatase and/or reduced myosin light-chain kinase levels. Furthermore, expression of phosphomimetic MLC largely prevented cytokinesis failure in the tested cancer cells. When myosin light-chain phosphorylation was restored to normal levels by phosphatase knockdown, multinucleation and multipolar mitosis were markedly reduced, resulting in enhanced genome stabilization. Furthermore, both overexpression of myosin phosphatase or inhibition of the myosin light-chain kinase in nonmalignant cells could recapitulate some of the mitotic defects of cancer cells, including multinucleation and multipolar spindles, indicating that these changes are sufficient to reproduce the cytokinesis failures we see in cancer cells. These results for the first time define the molecular defects leading to divisional failure in cancer cells.

Widespread genomic instability mediated by a pathway involving glycoprotein Ib alpha and Aurora B kinase

c-Myc (Myc) oncoprotein induction of genomic instability (GI) contributes to its initial transforming function and subsequent tumor cell evolution. We describe here a pathway by which Myc, via its target protein glycoprotein Ibalpha (GpIb alpha), mediates GI. Proteomic profiling revealed that the serine/threonine kinase Aurora B is down-regulated by GpIb alpha in p53-deficient primary human fibroblasts. The phenotypes of Aurora B deficiency are strikingly reminiscent of Myc or GpIb alpha overexpression and include double-stranded DNA breaks, altered nuclear size and morphology, chromatin bridges, cleavage furrow regression, and tetraploidy. During mitosis, GpIb alpha and Aurora B redistribute to the cleavage furrow along with other cleavage furrow proteins. GpIb alpha overexpression at levels comparable with those seen in some tumor cells causes the dispersal of these proteins but not Aurora B, resulting in furrow regression and cytokinesis failure. Aurora B normalization redirects the mislocalized furrow proteins to their proper location, corrects the cleavage furrow abnormalities, and restores genomic stability. Aurora B thus appears necessary for a previously unrecognized function in guiding and positioning a number of key proteins, including GpIb alpha to the cleavage furrow. These findings underscore the importance of maintaining a delicate balance among cleavage furrow-associated proteins during mitosis. Suppression of Aurora B via GpIb alpha provides a unifying and mechanistic explanation for several types of Myc-mediated GI.

Mitotic slippage in non-cancer cells induced by a microtubule disruptor, disorazole C1

Background

Disorazoles are polyene macrodiolides isolated from a myxobacterium fermentation broth. Disorazole C₁ was newly synthesized and found to depolymerize microtubules and cause mitotic arrest. Here we examined the cellular responses to disorazole C₁ in both non-cancer and cancer cells and compared our results to vinblastine and taxol.

Results

In non-cancer cells, disorazole C₁ induced a prolonged mitotic arrest, followed by mitotic slippage, as confirmed by live cell imaging and cell cycle analysis. This mitotic slippage was associated with cyclin B degradation, but did not require p53. Four assays for apoptosis, including western blotting for poly(ADP-ribose) polymerase cleavage, microscopic analyses for cytochrome C release and annexin V staining, and gel electrophoresis examination for DNA laddering, were conducted and demonstrated little induction of apoptosis in non-cancer cells treated with disorazole C₁. On the contrary, we observed an activated apoptotic pathway in cancer cells, suggesting that normal and malignant cells respond differently to disorazole C₁.

Conclusion

Our studies demonstrate that non-cancer cells undergo mitotic slippage in a cyclin B-dependent and p53-independent manner after prolonged mitotic arrest caused by disorazole C₁. In contrast, cancer cells induce the apoptotic pathway after disorazole C₁ treatment, indicating a possibly significant therapeutic window for this compound.

Microtubule binding and disruption and induction of premature senescence by disorazole C(1)

Disorazoles comprise a family of 29 macrocyclic polyketides isolated from the fermentation broth of the myxobacterium Sorangium cellulosum. The major fermentation product, disorazole A(1), was found previously to irreversibly bind to tubulin and to have potent cytotoxic activity against tumor cells, possibly because of its highly electrophilic epoxide moiety. To test this hypothesis, we synthesized the epoxide-free disorazole C(1) and found it retained potent antiproliferative activity against tumor cells, causing prominent G(2)/M phase arrest and inhibition of in vitro tubulin polymerization. Furthermore, disorazole C(1) produced disorganized microtubules at interphase, misaligned chromosomes during mitosis, apoptosis, and premature senescence in the surviving cell populations. Using a tubulin polymerization assay, we found disorazole C(1) inhibited purified bovine tubulin polymerization, with an IC(50) of 11.8 +/- 0.4 microM, and inhibited [3H]vinblastine binding noncompetitively, with a K(i) of 4.5 +/- 0.6 microM. We also found noncompetitive inhibition of [3H]dolastatin 10 binding by disorazole C(1), with a K(i) of 10.6 +/- 1.5 microM, indicating that disorazole C(1) bound tubulin uniquely among known antimitotic agents. Disorazole C(1) could be a valuable chemical probe for studying the process of mitotic spindle disruption and its relationship to premature senescence.

Actin and microtubules: working together to control spindle polarity

Centrosomes are frequently amplified in cancer cells, but centrosome clustering pathways act to minimize their detrimental impact on mitosis. Recent data published online in Genes & Developments by Kwon et al. (2008) suggest that these pathways involve microtubule motors, actin, and focal adhesions. Since centrosomal amplification is rarely seen in normal cells, could blocking clustering lead to the selective killing of tumor cells?

Relationship between FRA11F and 11q13 gene amplification in oral cancer

Common fragile sites (CFS) are nonstaining gaps or breaks in chromosomes that are expressed under conditions inducing replicative stress. CFS have been suggested to play a role in epithelial cancers by their association with loss of heterozygosity, loss of gene expression, and/or gene amplification in the form of homogeneously staining regions (hsrs). In oral squamous-cell carcinomas (OSCC), amplification of chromosomal band 11q13 occurs in the form of an hsr. We suggested previously that CFS flanking 11q13 may be susceptible to breakage induced by tobacco or other carcinogens and/or human papillomavirus, promoting formation of the 11q13 amplicon. Examination of OSCC cell lines with 11q13 amplification using fluorescence in situ hybridization showed loss of FRA11F sequences, whereas cell lines without 11q13 amplification displayed an intact FRA11F site. Cell lines with more complex 11q rearrangements expressed FRA11F in the form of an inverted duplication, characteristic of breakage-fusion-bridge cycles. Our findings suggest that gene amplification involving chromosomal band 11q13 in OSCC may be initiated by breakage at FRA11F.

Loss of distal 11q is associated with DNA repair deficiency and reduced sensitivity to ionizing radiation in head and neck squamous cell carcinoma

About 45% of head and neck squamous cell carcinomas (HNSCC) are characterized by amplification of chromosomal band 11q13. This amplification occurs by a breakage-fusion-bridge (BFB) cycle mechanism. The first step in the BFB cycle involves breakage and loss of distal 11q, from FRA11F (11q14.2) to 11qter. Consequently, numerous genes, including three critical genes involved in the DNA damage response pathway, MRE11A, ATM, and H2AFX are lost in the step preceding 11q13 amplification. We hypothesized that this partial loss of genes on distal 11q may lead to a diminished DNA damage response in HNSCC. Characterization of HNSCC using fluorescence in situ hybridization (FISH) revealed concurrent partial loss of MRE11A, ATM, and H2AFX in all four cell lines with 11q13 amplification and in four of seven cell lines without 11q13 amplification. Quantitative microsatellite analysis and loss of heterozygosity studies confirmed the distal 11q loss. FISH evaluation of a small series of HNSCC, ovarian, and breast cancers confirmed the presence of 11q loss in at least 60% of these tumors. All cell lines with distal 11q loss exhibited a diminished DNA damage response, as measured by a decrease in the size and number of gamma-H2AX foci and increased chromosomal instability following treatment with ionizing radiation. In conclusion, loss of distal 11q results in a defective DNA damage response in HNSCC. Distal 11q loss was also unexpectedly associated with reduced sensitivity to ionizing radiation. Although the literature attributes the poor prognosis in HNSCC to 11q13 gene amplification, our results suggest that distal 11q deletions may be an equally significant factor.

DNA repair pathways involved in anaphase bridge formation

Cancer cells frequently exhibit gross chromosomal alterations such as translocations, deletions, or gene amplifications an important source of chromosomal instability in malignant cells. One of the better-documented examples is the formation of anaphase bridges-chromosomes pulled in opposite directions by the spindle apparatus. Anaphase bridges are associated with DNA double strand breaks (DSBs). While the majority of DSBs are repaired correctly, to restore the original chromosome structure, incorrect fusion events also occur leading to bridging. To identify the cellular repair pathways used to form these aberrant structures, we tested a requirement for either of the two major DSB repair pathways in mammalian cells: homologous recombination (HR) and nonhomologous end joining (NHEJ). Our observations show that neither pathway is essential, but NHEJ helps prevent bridges. When NHEJ is compromised, the cell appears to use HR to repair the break, resulting in increased anaphase bridge formation. Moreover, intrinsic NHEJ activity of different cell lines appears to have a positive trend with induction of bridges from DNA damage.

Inverted duplication pattern in anaphase bridges confirms the breakage-fusion-bridge (BFB) cycle model for 11q13 amplification

The homogeneously staining region (hsr) involving chromosome band 11q13 includes amplified genes from this chromosome segment and carries a relatively poor prognosis in oral squamous cell carcinomas (OSCC), with shorter time to recurrence and reduced overall survival. We previously identified an inverted duplication pattern of genes within the 11q13 hsr in OSCC cells, supporting a breakage-fusion-bridge (BFB) cycle model for gene amplification. To validate our hypothesis that 11q13 gene amplification in OSCC occurs via BFB cycles, we carried out fluorescence in situ hybridization (FISH) using probes for band 11q13 on 29 OSCC cell lines. We demonstrate that all OSCC cell lines with 11q13 amplification express a significantly higher frequency of anaphase bridges containing 11q13 sequences compared to cell lines without amplification, providing further experimental evidence that 11q13 gene amplification in OSCC cells occurs via BFB cycles. Elucidation of mechanisms responsible for initiating and promoting gene amplification provides opportunities to identify new biomarkers to aid in the diagnosis and prognosis of oral cancer, and may be useful for developing novel therapeutic strategies for patients with OSCC.

Overexpression of Cdc20 leads to impairment of the spindle assembly checkpoint and aneuploidization in oral cancer

Defects in the spindle assembly checkpoint are thought to be responsible for an increased rate of aneuploidization during tumorigenesis. Despite a plethora of information on the correlation between BUB-MAD gene expression levels and defects in the spindle checkpoint, very little is known about alteration of another important spindle checkpoint protein, Cdc20, in human cancer and its role in tumor aneuploidy. We observed overexpression of CDC20 in several oral squamous cell carcinoma (OSCC) cell lines and primary head and neck tumors and provide evidence that such overexpression of CDC20 is associated with premature anaphase promotion, resulting in mitotic abnormalities in OSCC cell lines. We also reconstituted the chromosomal instability phenotype in a chromosomally stable OSCC cell line by overexpressing CDC20. Thus, abnormalities in the cellular level of Cdc20 may deregulate the timing of anaphase promoting complex (APC/C) in promoting premature anaphase, which often results in aneuploidy in the tumor cells.

Cik1 targets the minus-end kinesin depolymerase kar3 to microtubule plus ends

Kar3, a Saccharomyces cerevisiae Kinesin-14, is essential for karyogamy and meiosis I but also has specific functions during vegetative growth. For its various roles, Kar3 forms a heterodimer with either Cik1 or Vik1, both of which are noncatalytic polypeptides. Here, we present the first biochemical characterization of Kar3Cik1, the kinesin motor that is essential for karyogamy. Kar3Cik1 depolymerizes microtubules from the plus end and promotes robust minus-end-directed microtubule gliding. Immunolocalization studies show that Kar3Cik1 binds preferentially to one end of the microtubule, whereas the Kar3 motor domain, in the absence of Cik1, exhibits significantly higher microtubule lattice binding. Kar3Cik1-promoted microtubule depolymerization requires ATP turnover, and the kinetics fit a single exponential function. The disassembly mechanism is not microtubule catastrophe like that induced by the MCAK Kinesin-13s. Soluble tubulin does not activate the ATPase activity of Kar3Cik1, and there is no evidence of Kar3Cik1(.)tubulin complex formation as observed for MCAK. These results reveal a novel mechanism to regulate microtubule depolymerization. We propose that Cik1 targets Kar3 to the microtubule plus end. Kar3Cik1 then uses its minus-end-directed force to depolymerize microtubules from the plus end, with each tubulin-subunit release event tightly coupled to one ATP turnover.

Spindle multipolarity is prevented by centrosomal clustering

Most tumor cells are characterized by increased genomic instability and chromosome segregational defects, often associated with hyperamplification of the centrosome and the formation of multipolar spindles. However, extra centrosomes do not always lead to multipolarity. Here, we describe a process of centrosomal clustering that prevented the formation of multipolar spindles in noncancer cells. Noncancer cells needed to overcome this clustering mechanism to allow multipolar spindles to form at a high frequency. The microtubule motor cytoplasmic dynein was a critical part of this coalescing machinery, and in some tumor cells overexpression of the spindle protein NuMA interfered with dynein localization, promoting multipolarity.

Cigarette smoke induces anaphase bridges and genomic imbalances in normal cells

Exposure to cigarette smoke has long been linked to carcinogenesis, but the emphasis has been placed on mutational changes in the DNA sequence caused by the carcinogens in smoke. Here, we report an additional role for cigarette smoke exposure in contributing to chromosomal aberrations in cells. We have found that cigarette smoke condensate (CSC) induces anaphase bridges in cultured human cells, which in a short time lead to genomic imbalances. The frequency of the induced bridges within the entire population decreases with time, and this decrease is not dependent upon the p53-mediated apoptotic pathway. Additionally, we show that CSC induces DNA double stranded breaks (DSBs) in cultured cells and purified DNA. The reactive oxygen species (ROS) scavenger, 2' deoxyguanosine 5'-monophosphate (dGMP) prevents CSC-induced DSBs, anaphase bridge formation and genomic imbalances. Therefore, we propose that CSC induces bridges and genomic imbalances via DNA DSBs. Furthermore, since the amount of CSC added to the cultures was substantially less than that extracted from a single cigarette, our results show that even low levels of cigarette smoke can cause irreversible changes in the chromosomal constitution of cultured cells.

Resolution of anaphase bridges in cancer cells

Chromosomal instability is a key step in the generation of the cancer cell karyotype. An indicator of unstable chromosomes is the presence of chromatin bridges during anaphase. We examined in detail the fate of anaphase bridges in cultured oral squamous cell carcinoma cells in real-time. Surprisingly, chromosomes in bridges typically resolve by breaking into multiple fragments. Often these fragments give rise to micronuclei (MN) at the end of mitosis. The formation of MN is shown to have important consequences for the cell. We found that MN have incomplete nuclear pore complex (NPC) formation and nuclear import defects and the chromatin within has greatly reduced transcriptional activity. Thus, a major consequence of the presence of anaphase bridges is the regular sequestration of chromatin into genetically inert MN. This represents another source of ongoing genetic instability in cancer cells.

The occurrence of chromosome segregational defects is an intrinsic and heritable property of oral squamous cell carcinoma cell lines

Chromosomal segregational defects are commonly observed in cancer cells and are an important source of genetic instability. It is currently unknown whether these mitotic defects are the result of a subpopulation of defective cells or reflect characteristics of the population of cells as a whole. In this study, we compared chromosomal segregational defects in two oral squamous cell carcinoma cell lines and five single-cell clones from each of those cell lines. We used immunofluorescence microscopy to quantitate the occurrence of multipolar metaphase spindles, lagging chromosomes at metaphase and anaphase, and anaphase bridges. We conclude that chromosome segregational defects in these cancer cell lines represent an intrinsic and inherited tendency toward segregational defects in the general cell population, rather than the existence of a subpopulation of cells with segregational defects.

Chromosomal instability and marker chromosome evolution in oral squamous cell carcinoma

Squamous cell carcinoma of the head and neck and its subset, oral squamous cell carcinoma (OSCC), arise through a multistep process of genetic alterations as a result of exposure to environmental agents, such as tobacco smoke, alcoholic beverages, and viruses, including human papillomavirus. We and others have shown that the karyotypes of OSCC are near-triploid and contain multiple structural and numerical abnormalities. However, despite a background of clonal chromosomal aberrations, individual cells within a culture express many nonclonal numerical and structural abnormalities, termed chromosomal instability (CIN). To evaluate CIN in oral cancer cells, we isolated clones from two OSCC cell lines and carried out classical cytogenetic analysis, fluorescence in situ hybridization using centromere-specific probes, and spectral karyotyping. We observed variation in chromosome number within clones and between clones of the same cell line. Although similar numbers of centromeric signals for a particular chromosome were present, "homologs" of a chromosome varied structurally from cell to cell (marker chromosome evolution) as documented by classical and spectral karyotyping. In addition to the numerical chromosome variations within a clone, we observed marker chromosome evolution by structural chromosome alterations. It appears that both intrinsic structural alterations and extrinsic cytoskeletal factors influence chromosome segregation, resulting in individual tumor cells that express unique karyotypes. We show that CIN and marker chromosome evolution are essential acquired features of neoplastic cells. Proliferation of this heterogeneous cell population may provide some cells with the ability to evade standard therapies.

Large-scale functional genomic analysis of sporulation and meiosis in Saccharomyces cerevisiae

We have used a single-gene deletion mutant bank to identify the genes required for meiosis and sporulation among 4323 nonessential Saccharomyces cerevisiae annotated open reading frames (ORFs). Three hundred thirty-four sporulation-essential genes were identified, including 78 novel ORFs and 115 known genes without previously described sporulation defects in the comprehensive Saccharomyces Genome (SGD) or Yeast Proteome (YPD) phenotype databases. We have further divided the uncharacterized sporulation-essential genes into early, middle, and late stages of meiosis according to their requirement for IME1 induction and nuclear division. We believe this represents a nearly complete identification of the genes uniquely required for this complex cellular pathway. The set of genes identified in this phenotypic screen shows only limited overlap with those identified by expression-based studies.

The FEAR Before MEN: networks of mitotic exit

Variations in the normal regulation of the mitotic cell cycle can lead to such global cellular changes as differential development or malignant transformation. Studies on the control of mitosis are particularly important to discover the details of the basic mechanisms responsible for normal cell division, as well as to learn about strategies employed by cancerous cells to indefinitely proliferate. The past years have brought noteworthy progress in elucidating the molecular pathways that regulate crucial events during mitosis such as: chromosome condensation, formation of the mitotic spindle, chromosome segregation, cytokinesis, and disassembly of the mitotic spindle.

The FEAR factor

The decision to exit from mitosis is a fateful one, and Amon and colleagues have shown that it involves both an early and a late component. The FEAR network initiates the exit machinery, while the previously described MEN pathway maintains it.

RIM4 encodes a meiotic activator required for early events of meiosis in Saccharomyces cerevisiae

RIM4 was previously found to be required for both the IME1- and IME2-dependent pathways of meiotic gene expression in Saccharomyces cerevisiae. We now demonstrate that RIM4 is also required for meiotic division and recombination. Furthermore, rim4Delta mutants show defects in premeiotic DNA synthesis, which can be suppressed by deletion of the SIC1 gene, which encodes a Cdk inhibitor. Expression of RIM4 is induced early in meiosis, and is dependent on IME1 but not IME2. Indeed, RIM4 itself is essential for the meiotic expression of IME2. These results suggest that RIM4 is epistatic to IME2, and is required for multiple steps during sporulation. In agreement with this interpretation, overexpression of RIM4 induces low levels of sporulation in rich medium.

ADY1, a novel gene required for prospore membrane formation at selected spindle poles in Saccharomyces cerevisiae

ADY1 is identified in a genetic screen for genes on chromosome VIII of Saccharomyces cerevisiae that are required for sporulation. ADY1 is not required for meiotic recombination or meiotic chromosome segregation, but it is required for the formation of four spores inside an ascus. In the absence of ADY1, prospore formation is restricted to mainly one or two spindle poles per cell. Moreover, the two spores in the dyads of the ady1 mutant are predominantly nonsisters, suggesting that the proficiency to form prospores is not randomly distributed to the four spindle poles in the ady1 mutant. Interestingly, the meiosis-specific spindle pole body component Mpc54p, which is known to be required for prospore membrane formation, is localized predominantly to only one or two spindle poles per cell in the ady1 mutant. A partially functional Myc-Pfs1p is localized to the nucleus of mononucleate meiotic cells but not to the spindle pole body or prospore membrane. These results suggest that Pfs1p is specifically required for prospore formation at selected spindle poles, most likely by ensuring the functionality of all four spindle pole bodies of a cell during meiosis II.

The Saccharomyces cerevisiae centromere protein Slk19p is required for two successive divisions during meiosis

Meiotic cell division includes two separate and distinct types of chromosome segregation. In the first segregational event the sister chromatids remain attached at the centromere; in the second the chromatids are separated. The factors that control the order of chromosome segregation during meiosis have not yet been identified but are thought to be confined to the centromere region. We showed that the centromere protein Slk19p is required for the proper execution of meiosis in Saccharomyces cerevisiae. In its absence diploid cells skip meiosis I and execute meiosis II division. Inhibiting recombination does not correct this phenotype. Surprisingly, the initiation of recombination is apparently required for meiosis II division. Thus Slk19p appears to be part of the mechanism by which the centromere controls the order of meiotic divisions.

Chromosomal instability and cytoskeletal defects in oral cancer cells

Oral squamous cell carcinomas are characterized by complex, often near-triploid karyotypes with structural and numerical variations superimposed on the initial clonal chromosomal alterations. We used immunohistochemistry combined with classical cytogenetic analysis and spectral karyotyping to investigate the chromosomal segregation defects in cultured oral squamous cell carcinoma cells. During division, these cells frequently exhibit lagging chromosomes at both metaphase and anaphase, suggesting defects in the mitotic apparatus or kinetochore. Dicentric anaphase chromatin bridges and structurally altered chromosomes with consistent long arms and variable short arms, as well as the presence of gene amplification, suggested the occurrence of breakage-fusion-bridge cycles. Some anaphase bridges were observed to persist into telophase, resulting in chromosomal exclusion from the reforming nucleus and micronucleus formation. Multipolar spindles were found to various degrees in the oral squamous cell carcinoma lines. In the multipolar spindles, the poles demonstrated different levels of chromosomal capture and alignment, indicating functional differences between the poles. Some spindle poles showed premature splitting of centrosomal material, a precursor to full separation of the microtubule organizing centers. These results indicate that some of the chromosomal instability observed within these cancer cells might be the result of cytoskeletal defects and breakage-fusion-bridge cycles.

Slk19p is a centromere protein that functions to stabilize mitotic spindles

We have identified a novel centromere-associated gene product from Saccharomyces cerevisiae that plays a role in spindle assembly and stability. Strains with a deletion of SLK19 (synthetic lethal Kar3p gene) exhibit abnormally short mitotic spindles, increased numbers of astral microtubules, and require the presence of the kinesin motor Kar3p for viability. When cells are deprived of both Slk19p and Kar3p, rapid spindle breakdown and mitotic arrest is observed. A functional fusion of Slk19p to green fluorescent protein (GFP) localizes to kinetochores and, during anaphase, to the spindle midzone, whereas Kar3p-GFP was found at the nuclear side of the spindle pole body. Thus, these proteins seem to play overlapping roles in stabilizing spindle structure while acting from opposite ends of the microtubules.

Action at the ends of microtubules

Microtubule-based motility in the cell is directly associated with changes in microtubule numbers through nucleation and growth and shrinkage of the polymer from the ends. Recent analysis of spindle pole bodies and kinetochores in yeast reveal how the cell builds specialized structures for association with the ends of microtubules.

The Kar3p and Kip2p motors function antagonistically at the spindle poles to influence cytoplasmic microtubule numbers

Microtubules provide the substrate for intracellular trafficking by association with molecular motors of the kinesin and dynein superfamilies. Motor proteins are generally thought to function as force generating units for transport of various cargoes along the microtubule polymer. Recent work suggests additional roles for motor proteins in changing the structure of the microtubule network itself. We report here that in the budding yeast Saccharomyces cerevisiae microtubule motors have antagonistic effects on microtubule numbers and lengths. As shown previously, loss of the Kar3p motor stimulates cytoplasmic microtubule growth while loss of Kip2p leads to a sharp reduction in cytoplasmic microtubule numbers. Loss of both the Kip2p and Kar3p motors together in the same cell produces an intermediate phenotype, suggesting that these two motors act in opposition to control cytoplasmic microtubule density. A Kip2p-GFP fusion from single gene expression is most concentrated at the spindle poles, as shown previously for an epitope tagged Kar3p-HA, suggesting both of these motors act from the minus ends of the microtubules to influence microtubule numbers.

Saccharomyces cerevisiae kinesin- and dynein-related proteins required for anaphase chromosome segregation

The Saccharomyces cerevisiae kinesin-related gene products Cin8p and Kip1p function to assemble the bipolar mitotic spindle. The cytoplasmic dynein heavy chain homologue Dyn1p (also known as Dhc1p) participates in proper cellular positioning of the spindle. In this study, the roles of these motor proteins in anaphase chromosome segregation were examined. While no single motor was essential, loss of function of all three completely halted anaphase chromatin separation. As combined motor activity was diminished by mutation, both the velocity and extent of chromatin movement were reduced, suggesting a direct role for all three motors in generating a chromosome-separating force. Redundancy for function between different types of microtubule-based motor proteins was also indicated by the observation that cin8 dyn1 double-deletion mutants are inviable. Our findings indicate that the bulk of anaphase chromosome segregation in S. cerevisiae is accomplished by the combined actions of these three motors.

Mitotic spindle pole separation

Eukaryotic cells utilize a microtubular spindle to segregate chromosomes during mitosis. Chromosome segregation requires the timely separation of the mitotic spindle poles to which the chromosomes are attached. Recent studies at the molecular and cellular levels have provided new insights into the mechanism and regulation of this process. On the one hand, the process now seems more complex, as redundant mechanisms apparently overlap in function during cell division. On the other hand, some of these processes may be acting continuously during the various stages of spindle pole separation, suggesting an underlying simplicity.

Loss of function of Saccharomyces cerevisiae kinesin-related CIN8 and KIP1 is suppressed by KAR3 motor domain mutations

The kinesin-related products of the CIN8 and KIP1 genes of Saccharomyces cerevisiae redundantly perform an essential function in mitosis. The action of either gene-product is required for an outwardly directed force that acts upon the spindle poles. We have selected mutations that suppress the temperature-sensitivity of a cin8-temperature-sensitive kip1-delta strain. The extragenic suppressors analyzed were all found to be alleles of the KAR3 gene. KAR3 encodes a distinct kinesin-related protein whose action antagonizes Cin8p/Kip1p function. All seven alleles analyzed were altered within the region of KAR3 that encodes the putative force-generating (or "motor") domain. These mutations also suppressed the inviability associated with the cin8-delta kip1-delta genotype, a property not shared by a deletion of KAR3. Other properties of the suppressing alleles revealed that they were not null for function. Six of the seven were unaffected for the essential karyogamy and meiosis properties of KAR3 and the seventh was dominant for the suppressing trait. Our findings suggest that despite an antagonistic relationship between Cin8p/Kip1p and Kar3p, aspects of their mitotic roles may be similar.

Molecular cloning of a human homologue of Drosophila heterochromatin protein HP1 using anti-centromere autoantibodies with anti-chromo specificity

We have identified a novel autoantibody specificity in scleroderma that we term anti-chromo. These antibodies recognize several chromosomal antigens with apparent molecular mass of between 23 and 25 kDa, as determined by immunoblots. Anti-chromo autoantibodies occur in 10–15% of sera from patients with anti-centromere antibodies (ACA). We used anti-chromo antibodies to screen a human expression library and obtained cDNA clones encoding a 25 kDa chromosomal autoantigen. DNA sequence analysis reveals this protein to be a human homologue of HP1, a heterochromatin protein of Drosophila melanogaster. We designate our cloned protein HP1Hs alpha. Epitope mapping experiments using both human and Drosophila HP1 reveal that anti-chromo antibodies target a region at the amino terminus of the protein. This region contains a conserved motif, the chromo domain (or HP1/Pc box), first recognized by comparison of Drosophila HP1 with the Polycomb gene product. Both proteins are thought to play a role in creating chromatin structures in which gene expression is suppressed. Anti-chromo thus defines a novel type of autoantibody that recognizes a conserved structural motif found on a number of chromosomal proteins.

Kinesin-related proteins required for structural integrity of the mitotic spindle

For S. cerevisiae cells, the assembly of a bipolar mitotic spindle requires the action of either Cin8p or Kip1p, gene products related to the mechanochemical enzyme kinesin. In this paper we demonstrate that the activity of either one of these proteins is also required following spindle assembly. When their function was eliminated, preanaphase bipolar spindles rapidly collapsed, with previously separated poles being drawn together. In contrast, anaphase spindles were apparently resistant to collapse. Deletion of kinesin-related KAR3 partially suppressed the phenotypes associated with loss of Cin8p/Kip1p function. Our findings suggest that the structure of the preanaphase bipolar spindle is maintained by counteracting forces produced by kinesin-related proteins.

Two Saccharomyces cerevisiae kinesin-related gene products required for mitotic spindle assembly

Two Saccharomyces cerevisiae genes, CIN8 and KIP1 (a.k.a. CIN9), were identified by their requirement for normal chromosome segregation. Both genes encode polypeptides related to the heavy chain of the microtubule-based force-generating enzyme kinesin. Cin8p was found to be required for pole separation during mitotic spindle assembly at 37 degrees C, although overproduced Kip1p could substitute. At lower temperatures, the activity of at least one of these proteins was required for cell viability, indicating that they perform an essential but redundant function. Cin8p was observed to be a component of the mitotic spindle, colocalizing with the microtubules that lie between the poles. Taken together, these findings suggest that these proteins interact with spindle microtubules to produce an outwardly directed force acting upon the poles.

Compartmentalization within the nucleus: discovery of a novel subnuclear region

Antibodies to a set of structurally related autoantigens (p23-25) bind to a previously uncharacterized, large structural domain in the nucleus of a variety of human cell types. This subnuclear domain is visible by phase contrast alone as a region of decreased density after several different fixation protocols. The morphology of this region changes dramatically during the cell cycle and we have given it the name PIKA (for polymorphic interphase karyosomal association) based on preliminary evidence that the PIKA proteins may be associated with chromatin. The function of the PIKA is not yet known, but our immunolocalization data indicate that it is unlikely to be associated with regions of ongoing DNA replication, heterogeneous nuclear RNA storage, or mRNA processing. The discovery of the PIKA provides evidence supporting an emerging model of nuclear structure. It now appears that the nucleus is organized into distinct domains which include not only the nucleolus, but also previously unidentified regions such as the PIKAs. Furthermore, structural rearrangements undergone by the nucleolus and the PIKAs may be indicative of a broad tendency for nuclear organization to change in a cell cycle-specific fashion.

Isolation of a human epidermal cDNA corresponding to the 180-kD autoantigen recognized by bullous pemphigoid and herpes gestationis sera. Immunolocalization of this protein to the hemidesmosome

Autoantibodies present in the sera of patients with bullous pemphigoid (BP) bind to the basement membrane zone of normal human skin and commonly recognize two epidermal proteins, the BP240 and BP180 antigens. Two BP antigen cDNA clones from a lambda gt11 human keratinocyte library have been identified on the basis of reactivity with a BP serum. The fusion protein (FP) produced by one clone immunoadsorbed autoantibodies, which specifically recognized the BP180 by antigen, showing no cross-reactivity with BP240 by immunoblot analysis. The FP produced by the second clone immunoadsorbed autoantibodies which specifically reacted with the BP240 epidermal antigen. Northern blot analysis demonstrated that the BP180 and BP240 antigens are encoded by distinct RNA transcripts with lengths of 6.0 and 8.5 kb, respectively. Immunoblot analysis of the BP180 lysogen extract identified a 135-kD FP which was recognized by 7 of 16 BP sera and 7 of 8 herpes gestationis sera. A rabbit antiserum prepared against the lysogenic BP180 FP specifically recognized the BP180 antigen from human epidermal extracts by immunoblotting, labeled the BMZ by indirect immunofluorescence, and bound to human epidermal hemidesmosomes by immuno-electron microscopy. These results indicate that the BP180 antigen recognized by BP and herpes gestationis autoantibodies is a unique hemidesmosomal polypeptide, distinguishable from the BP240 antigen.

Opiate and alpha receptor antagonists block the pressor responses of conscious rats given intravenous dynorphin

Conscious, unrestrained rats were used to determine the hemodynamic (blood pressure and heart rate) responses following intravenous (IV) injection of dynorphin A(1-13) and the possible receptor mechanisms mediating those changes. Male Sprague-Dawley rats (300 g) were given IV bolus injections (via femoral venous catheter) of 6.0 to 600 nmoles/kg of dynorphin A(1-13), 8.0 nmoles/kg of norepinephrine HCl (NE), 14.3 pmoles/kg of angiotensin II or a vehicle control solution. Blood pressure (BP) and heart rate (HR) were monitored via femoral arterial catheter (into abdominal aorta) over 90 sec postpeptide or -amine administration before and 10 min after IV injection of 4.2 mumoles/kg of naloxone HCl (opiate antagonist), yohimbine HCl (alpha 2 receptor antagonist) or prazosin HCl (alpha 1 receptor antagonist). Dynorphin A(1-13) caused a transient but dose-related rise in mean arterial pressure (MAP) whereas mean pulse pressures (MPP) and mean heart rates (MHR) concomitantly fell, from preinjection control values in a dose-dependent fashion. Pretreatment with naloxone blocked the pressor response of only a subsequent injection with 20 nmoles/kg but not 60 nmoles/kg of dynorphin A or NE (8.0 nmoles/kg). Pretreatment with yohimbine suppressed the marked pressor responses of subsequent NE or Dyn A (60 nmoles/kg) administration whereas prazosin antagonized the rise in MAP of only the lower doses of dynorphin as well as NE. The suppression of the pressor responses of dynorphin by opiate or alpha receptor antagonists were not caused by tachyphylaxis for repeated injections of 6.0 or 60 nmoles/kg of dynorphin caused the same rise in MAP.(ABSTRACT TRUNCATED AT 250 WORDS)

Pressor, tachycardic and feeding responses in conscious rats following i.c.v. administration of dynorphin. Central blockade by opiate and alpha 1-receptor antagonists

Experiments were designed to determine the hemodynamic responses of conscious, unrestrained rats given intracerebroventricular (i.c.v.) injections of dynorphin A-(1-13) and the possible central receptor mechanisms mediating those changes. Male Sprague-Dawley rats (300 gb. wt.) received i.c.v. injections (by gravity flow in a total volume of 3 or 5 microliter) of control solutions of sterile saline (SS) or dimethylsulfoxide (DMSO) or 1.5, 3.0 or 6.1 nmol of dynorphin A-(1-13). Blood pressure and heart rate changes were monitored over 2 h after administration; as well, feeding activity was visually assessed and scored over this period. Other groups of conscious rats were pretreated i.c.v. with equimolar doses (3.0-24.4 nmol) of specific receptor antagonists (naloxone HCl, phentolamine HCl, propranolol HCl, yohimbine HCl or prazosin HCl) 10 min before subsequent i.c.v. administration of SS or DMSO/SS or 6.1 nmol of dynorphin A-(1-13). I.c.v. injection of dynorphin A-(1-13) caused a dose-related pressor response, associated temporally with tachycardia. As well, dynorphin evoked feeding activity and some grooming, which occurred when the rats were hypertensive and tachycardic and decreased as heart rate and blood pressure returned to control levels. I.c.v. pretreatment studies indicated that naloxone HCl (12.2 nmol), phentolamine HCl (12.2 nmol) and prazosin HCl (6.1 nmol) blocked the pressor response, tachycardia as well as feeding activity of rats subsequently given dynorphin. The results suggest the pressor and tachycardic effects of conscious rats following i.c.v. dynorphin administration may, in part, be due to behavioral activation (feeding). As well, these data indicate that both opioid as well as alpha 1-adrenergic receptors within the CNS are involved in mediating the pressor, tachycardic and feeding responses of conscious rats given i.c.v. injections of dynorphin A.

Skeletal muscle thermogenesis: its role in the hyperthermia of conscious rats given morphine or beta-endorphin

The role of skeletal muscle thermogenesis (increases in skeletal muscle tone) in the hyperthermic responses of conscious, unrestrained rats given acute or repeated i.p. or i.c.v. injections of morphine sulfate (MS) or beta-endorphin was investigated. Initial blood gas experiments showed that rats given acute i.p. injections of MS caused PO2 and pH to decrease by 60 min postadministration in a dose-related fashion whereas PCO2 increased; with repeated MS administration the respiratory acidosis seen with acute injections was reduced. Acute i.p. injections of MS (1, 10 or 20 mg/kg) caused catalepsy scores, plasma lactate levels and electromyographic (EMG) amplitude to be elevated in a dose-related fashion along with a rise in rectal temperatures (TRS). Surface (tail) temperatures also rose after the acute MS injections but only after the increase in TR. Significant increases in EMG amplitude after acute injections of MS occurred even before TRS increased and, with subsequent naloxone HCl administration (10 mg/kg i.p.), a rapid and marked fall in EMG amplitude occurred before TRS fell back to saline control levels. Acute i.c.v. injections of 1.1 nmol of either MS or beta-endorphin also caused EMG amplitudes to rise significantly before TRS began to increase. Tail temperatures again increased passively after i.c.v. injection of either drug. Subsequent naloxone injections (10 mg/kg i.p.) to these groups also caused EMG amplitudes to decrease before TRS decreased back to control TRS. Repeated i.p. injections of MS (10 mg/kg i.p. daily for 5 days) caused TRS to be higher than those seen after the initial injection but catalepsy scores, plasma lactates and EMG amplitudes were below those respective levels seen upon acute MS administration. Similar chronic findings occurred in other groups of rats given 1.1 nmol of either MS or beta-endorphin i.c.v., when they had been previously given repeated i.p. injections of MS (5 mg/kg i.p. twice daily for 2 days). The results indicate that acute peripheral or central injections of MS or beta-endorphin to conscious rats cause skeletal muscle to be activated, resulting in nonlocomotor, catatonic behavior. This skeletal muscle activation occurs before the rise in TR and is thought to be an important and possibly the primary cause of the resultant hyperthermia seen in rats after acute central or peripheral administration of MS or beta-endorphin. Repeated injections of morphine cause TRS to escalate higher, compared to that seen with acute MS administration, yet catalepsy scores, plasma lactate levels and EMG amplitude changes did not increase likewise.(ABSTRACT TRUNCATED AT 400 WORDS)

Pressor effects of systemic administration of methionine and leucine enkephalin in the conscious rat

Experiments were designed using conscious Sprague-Dawley rats to determine the blood pressure (BP) and heart rate (HR) responses to intravenous doses of (1) the adrenal catecholamines noradrenaline (NA) and adrenaline (A), (2) adrenal pentapeptides methionine enkephalin (ME) and leucine enkephalin (LE), (3) combination (i.v.) injections of both ME or LE with NA or A that modulate the hemodynamic responses when the adrenal catecholamines were given alone, and (4) the possible receptor mechanisms mediating the resultant BP and HR response to i.v. pentapeptide administration. NA (0.48 and 2.4 nmol) and A (0.3 and 1.5 nmol) given i.v. evoked potent, dose-related pressor responses associated with reflex bradycardia. ME and LE (1.6 - 48 nmol) elicited transient (10-20 s) increases in mean arterial pressure (MAP), which was associated either with no change in mean heart rate (MHR), such as ME, or with slight bradycardia (i.e., LE). Combining ME or LE (16 nmol) with NA (2.4 nmol) or A (0.3 or 1.5 nmol) did not change MAP and MHR from when these respective doses of NA or A were given alone. However, 16 nmol of ME or LE with a low dose of NA (0.48 nmol) increased the pressor response compared with NA (0.48 nmol) given alone. Other experiments whereby specific receptor blockers (naloxone, diprenorphine, atropine, propranolol, phentolamine or guanethidine) were given i.v. 5 min before subsequent i.v. administration of LE or ME (16 nmol) indicated that only phentolamine or guanethidine could completely suppress the pressor responses of LE and ME. Naloxone and diprenorphine pretreatment attenuated the pressor response of LE but did not affect the BP response to ME.(ABSTRACT TRUNCATED AT 250 WORDS)

Pressor, tachycardic and behavioral excitatory responses in conscious rats following ICV administration of ACTH and CRF are blocked by naloxone pretreatment

Experiments were conducted to compare the blood pressure and heart rate responses of conscious rats given intracerebroventricular (ICV) injections of adrenocorticotropin (ACTH 1-24) and corticotropin releasing factor (CRF). Under sodium pentobarbital anaesthesia, rats were implanted with a stainless-steel cannula into the lateral cerebral ventricle and had their right femoral artery and vein cannulated. Upon recovery (24-48 hr later) conscious, unrestrained rats were given ICV injections (total volume 5 microliter by gravity flow) of sterile saline, ACTH (1-24) (0.85 and 1.7 nmoles) or CRF (0.55 and 1.1 nmoles) and blood pressure and heart rate were monitored over the next 2 hr (from the abdominal aorta via the femoral arterial catheter). Both ACTH and CRF caused mean arterial pressure (MAP) to increase, which was paralleled with increases in mean heart rate (MHR). Moreover, these elevations in MAP and MHR were temporally associated with excessive grooming (for ACTH) and locomotor activity (for CRF), which occurred before and lasted as long as MAP and MHR were enhanced. Intravenous (IV) pretreatment whereby naloxone was given 10 min before ICV administration of ACTH (1.7 nmoles) or CRF (1.1 nmoles), showed that naloxone blocked the behavioral, pressor and tachycardic effects of both ACTH and CRF. The results demonstrate that the pressor, tachycardic and locomotor effects evoked in conscious rats by ICV administration of ACTH or CRF are antagonized by naloxone and that their hemodynamic changes may, in part, be mediated by prior behavioral activation.

The role of the pituitary-adrenal axis in the hyperthermia induced by acute peripheral or central (preoptic anterior hypothalamus) administration of morphine to unrestrained rats

The role of the pituitary-adrenal axis in the mediation of morphine-induced hyperthermia of conscious, unrestrained rats was investigated. Rectal (TR) and tail (Tt) temperatures and oxygen uptake rates (VO2) were measured following peripheral or central injection of morphine sulphate (MS) in groups of Sprague-Dawley rats before and after adrenalectomy (adx), hypophysectomy (hyp), or pituitary suppression (via dexamethasone treatment). The hyperthermic TR responses of groups given MS either subcutaneously (5 or 15 mg/kg) or directly into the preoptic anterior hypothalamus (POAH, 1 or 10 micrograms/microL) before adx were not different upon retesting with the same dose of MS 2 weeks later following adx. The hyperthermia with MS was not caused by vasoconstriction or by increases in basal metabolic rate, for Tt rose after the opiate injections whereas oxygen uptake rates (VO2) were reduced. Unexpectedly, the TR following POAH injections of sterile saline (SS) or deionized water after adx increased from those seen before adx. Adx groups supplemented with dexamethasone phosphate (either chronically with 20 micrograms/kg daily for 2 weeks post-adx before retesting with MS or acutely with 250 micrograms/kg 2 h before retesting) showed a hyperthermia to MS (5 mg/kg sc or 1.0 microgram/microL POAH) similar to that seen before adx. However, dexamethasone phosphate (250 micrograms/kg) supplementation to adx rats, that received POAH injections of SS, did reduce the rise in TR. Hyp rats given MS (5 mg/kg, sc) also evoked hyperthermic responses similar to those of non-hyp control groups. The results clearly show that the acute hyperthermia of unrestrained rats induced by either peripheral or central injections of morphine is not caused by activation of the pituitary-adrenal axis.

Blood pressure responses of conscious rats to intravenous administration of enkephalin derivatives (D-ala2 methionine and leucine enkephalinamide, and methionine and leucine enkephalinamide

The present study was designed to determine the blood pressure (BP) responses of conscious rats given intravenous (IV) injections of enkephalin derivatives (D-ala2-methionine enkephalinamide, DAMEA; D-ala2-leucine enkephalinamide, DALEA; methionine enkephalinamide, MEA; leucine enkephalinamide, LEA) and the receptor mechanisms mediating the resultant change in BP. IV injection of 1.6-16.0 nmoles of DAMEA or DALEA caused a transient but potent decrease in mean arterial pressure (MAP) and mean heart rate (MHR). LEA and MEA (16.0 nmoles) given IV produced slight pressor responses, which were not associated with concomitant tachycardia whereas 48 nmoles of MEA elicited a hypotensive effect accompanied by a fall in MHR. Pretreatment studies whereby various receptor antagonists (naloxone, diprenorphine, phentolamine, D-L-propranolol or atropine) were given IV 5 min before subsequent IV administration of DAMEA, DALEA, MEA or LEA (16 nmoles) showed that naloxone, diprenorphine and atropine blocked the depressor and bradycardic effects of DALEA and DAMEA. Naloxone and phentolamine suppressed the pressor response of both MEA and LEA (16.0 nmoles) while diprenorphine blocked the rise in MAP to only MEA. The results show that DAMEA and DALEA mediate their depressor actions in conscious rats via a negative chronotropic effect through an interaction of muscarinic cholinergic receptors on the myocardium. It suggested that the pressor response of MEA and LEA may be produced via an alpha-receptor mediated effect on the peripheral vasculature to cause vasoconstriction.

No inotropic action of enkephalins or enkephalin derivatives on electrically-stimulated atria isolated from lean and obese rats

Inotropic actions of the endogenous enkephalins, leucine enkephalin [( Leu] enkephalin) and methionine enkephalin [( Met] enkephalin), and derivatives, [D-Ala2-methionine] enkephalinamide (DAMEA) and [D Ala2-leucine]enkephalinamide (DALEA) were tested, alone or in combination with noradrenaline (NA), (+/-)-isoprenaline or carbachol, on electrically-stimulated atria excised from Sprague-Dawley, fatty, Zucker (fa/fa) and lean, hooded heterozygous (Fa/fa) rats. [Met] enkephalin, [Leu] enkephalin, DAMEA and DALEA (4 X 10(-7)M to 4 X 10(-4)M) caused no significant changes in atrial tension in any group compared to pre-injection control values or those following the infusion of Krebs-Henseleit control solution. NA and isoprenaline (10(-7) to 10(-6)M) caused significant, dose-related increases in atrial tension in each of the three strains of rats tested with the Fa/fa group showing the greatest change and fastest rate of tension development. [Met] enkephalin, [Leu] enkephalin, DAMEA or DALEA (4 X 10(-6)M) infused concurrently with NA or isoprenaline (10(-6)M) evoked atrial tension changes within each group that were not different from those observed when NA or isoprenaline was administered alone. Carbachol (10(-9) and 10(-8)M) caused a dose-related decrease (10% and 30-40%, respectively, from pre-injection control values) in atrial tension in auricles excised from all three groups. Again, infusion of [Met] enkephalin, [Leu] enkephalin, DAMEA or DALEA (4 X 10(-6)M) together with carbachol (10(-8)M) did not affect atrial tension changes of auricles isolated from any group compared to when carbachol was given alone. The results indicate that the endogenous pentapeptides, [( Met] or [Leu] enkephalin), or derivatives (DAMEA and DALEA) do not affect atrial tension of electrically-stimulated auricles isolated from Sprague-Dawley, fa/fa or Fa/fa rats. In addition, these pentapeptides do not modify the positive inotropic actions of NA or isoprenaline or the negative inotropic effects of carbachol. It is suggested that in vivo, the enkephalins or enkephalin derivatives do not have a direct action on the heart to alter myocardial contractility.

Thermoregulatory (core, surface and metabolic) responses of unrestrained rats to repeated POAH injections of beta-endorphin or adrenocorticotropin

Repeated preoptic-anterior hypothalamic (POAH) injections of saline and 10 or 25 micrograms/microliters of beta-endorphin or ACTH were given to groups of male Sprague-Dawley rats. One hr after the fifth injection of beta-endorphin or ACTH, each rat received a POAH injection of naloxone HCl (10 micrograms/microliters). Core (Tre-rectal) and surface (Tt-tail) temperatures, metabolic (VO2) and behavioral responses were recorded 30 min before and 60 min after each drug injection. The initial POAH injection of either dose of beta-endorphin produced a hyperthermia. Peak hyperthermia was reduced in the group given 10 micrograms/microliters of beta-endorphin repeatedly. TtS rose after each beta-endorphin injection but temporally lagged Tre increases. Metabolic rate (VO2) was increased with repeated POAH injections of beta-endorphin. Naloxone reduced the elevated Tre seen with beta-endorphin by increasing Tt's further and reducing VO2. POAH administration of ACTH evoked only a slight hyperthermic Tre response, but elevated TtS and VO2S, due to enhanced grooming and explorative behavior. With repeated ACTH injections, TreS did not change from those on the first day as TtS and VO2 remained enhanced. Naloxone reduced VO2 and TtS of the ACTH-treated rats but TreS still were unchanged. Results suggest that the hyperthermia of unrestrained rats given an acute as opposed to repeated POAH beta-endorphin injections is mediated by different effector mechanisms. With the doses used, the slight and unchanging TreS seen with ACTH occurred because this peptide increased heat production due to locomotor activation yet also exaggerated heat loss by vasodilating the peripheral vasculature.

Acute stimulation of feeding with repeated injections of morphine sulphate to non-obese and fatty Zucker rats

Food intake studies with genetically obese rodents show that these hyperphagic animals, which have increased central and peripheral levels of endogenous opioid peptides (E.O.P.), have an increased sensitivity to the suppressive feeding effects of narcotic antagonists compared to lean controls. Feeding experiments were conducted to determine if genetically obese rats, with enhanced E.O.P., have a reduced sensitivity toward the narcotic agonist property of stimulated feeding seen in non-obese rats. Food intake was monitored continuously over each experimental day in groups of female Sprague-Dawley (S.D.,), fatty Zucker (fa/fa) and their lean heterozygote littermates (Fa/fa) following subcutaneous a.m. injections of sterile saline, morphine sulphate (5 or 10 mg/kg) or naloxone HCl (10 mg/kg) and during recovery. Acute 4-h post-injection feeding was reduced in all groups with the first 10 mg/kg injection of morphine sulphate. With repeated morphine administration, a phase of stimulated feeding occurred in both obese and non-obese groups. Due to the post-injection phase of vigorous feeding with repeated morphine injections, the circadian pattern of day/night food intake of all groups was altered such that daytime feeding increased from saline control levels. Naloxone HCl abolished the post-injection phase of stimulated feeding seen with chronic morphine injections and reduced 4-h post-injection food intakes. Plasma glucose and serum insulin levels were decreased in non-obese rats from saline controls of blood samples taken 2-h following the 7th daily M.S. injection. These levels increased again by the end of the recovery period. No blood glucose or insulin changes were seen in the obese Zucker rats with morphine administration.(ABSTRACT TRUNCATED AT 250 WORDS)