MASTL is the human ortholog of Greatwall kinase that facilitates mitotic entry,anaphase and cytokinesis

Greatwall (Gwl) was originally discovered in Drosophila as an essential kinase for correct chromosome condensation and mitotic progression. In Xenopus, Gwl may influence the positive-feedback loop that directs cyclin B1-Cdk1 activation and the mitotic state by inhibiting the phosphatase PP2A. Here, we describe the human orthologue of Gwl called microtubule-associated serine/threonine kinase-like (MASTL). We found that MASTL localizes to the nucleus in interphase and re-localizes in part to centrosomes in mitosis, when it is active. Cells strongly depleted of MASTL by RNAi delay in G2 phase and reveal slow chromosome condensation. MASTL RNAi cells that enter and progress through mitosis often fail to completely separate their sister chromatids in anaphase. This causes chromatin to be trapped in the cleavage furrow, which may lead to formation of 4N G1 cells by cytokinesis failure. Further, our experiments indicate that MASTL supports the phosphorylation state of mitotic phospho-proteins downstream of cyclin B1-Cdk1, including the APC/C. Cyclin B1 destruction is incomplete when mitotic cells that are strongly depleted of MASTL exit mitosis. We propose that MASTL enhances cyclin B1-Cdk1-dependent mitotic phosphorylation-events, directing mitotic entry, anaphase and cytokinesis in human cells.     

Expression of the intercellular adhesion molecule-1 on high endothelial venules and on non-lymphoid antigen handling cells: interdigitating cells,antigen transporting cells and follicular dendritic cells

Intercellular adhesion molecule-1 (ICAM-1)¹ has been implicated in the development of germinal center reactions in vitro, and the present study was undertaken to determine the distribution of ICAM-1 in active germinal centers in vivo and in murine secondary lymphoid tissues in general. Anti-ICAM-1-specific monoclonal antibodies were used in conjunction with immunohistochemistry at both the light and ultrastructural levels of resolution. Examination of cryostat sections of lymph nodes, spleens, and Peyer's patches revealed that anti-ICAM-1 distinctly labeled cells in the light zones of germinal centers, a few cells in the T cell zones (e.g. paracortex of lymph nodes), cells in the sinus floor of the subcapsular sinuses of lymph nodes, and high endothelial venules (HEV). Ultrastructural studies revealed that the cells labeling with anti-ICAM-1 in germinal centers were follicular dendritic cells (FDC) which appeared to have more ICAM-1 than any other cell type. The surfaces of well-developed, intricate, convoluted FDC processes were intensely labeled even under conditions where B cells appeared negative. Interdigitating cells (IDC) were also labeled as were certain endothelial cells in the HEV. The cells in the subcapsular sinus floor labeling with anti-ICAM-1 were the antigen transporting cells (ATC) that carry antigen-antibody complexes into lymph node follicles. We suspect ATC are FDC precursors which mature into FDC in the follicles. Interestingly, FDC, IDC, and ATC are 3 important accessory cells known to handle antigens in specific compartments of lymphoid tissues. The marked localization of this adhesion molecule on these critical antigen handling cells supports the concept that ICAM-1 is important in providing the intercellular adhesion necessary for optimal initiation of immune responses in vivo.Abbreviations ICAM-1 Intercellular adhesion molecule-1 - LFA-1 leukocyte functional antigen-1 - IDC interdigitating cells - ATC antigen transporting cells - FDC follicular dendritic cells - HEV high endothelial venules - DC dendritic cells - PBS phosphate-buffered saline - PLP periodate-lysine-4% paraformaldehyde - GPLP periodate-lysine-0.1% glutaraldehyde-2% paraformaldehyde - EM electron microscopy - HRP horseradish peroxidase - DAB diaminobenzidine tetrahydrochloride - HSA human serum albumin     

Phosphorylation of non-histone proteins associated with mitosis in HeLa cells

Our previous studies indicated that certain non-histone proteins (NHP) extractable with 0.2 M NaCl from mitotic HeLa cells induce germinal vesicle breakdown and chromosome condensation in Xenopus laevis oocytes. Since the maturation-promoting activity of the mitotic proteins is stabilized by phosphatase inhibitors, we decided to examine whether phosphorylation of NHP plays a role in the condensation of chromosomes during mitosis. HeLa cells, synchronized in S phase, were labeled with ³²P at the end of S phase, and the cells subsequently collected while they were in G2, mitosis, or G1. Cytoplasmic, nuclear, or chromosomal proteins were extracted and separated by gel electrophoresis. The labeled protein bands were detected by radioautography. The results indicated an 8–10-fold increase in the phosphorylation of NHP from mid-G2 to mitosis, followed by a similar-size decrease as the cells divided and entered G1. The NHP phosphorylation rate increased progressively during G2 traverse and reached a peak in mitosis. Radioautography of the separated NHP revealed eight prominent, extensively phosphorylated protein bands with molecular masses ranging from 27.5 to 100 kD. These NHP were rapidly dephosphorylated during M-G1 transition. Phosphorylation—dephosphorylation of NHP appeared to be a dynamic process, with the equilibrium shifting to phosphorylation during G2-M and dephosphorylation during M-G1 transitions. These results suggest that besides histone H1 phosphorylation, phosphorylation of this subset of NHP may also play a part in mitosis.     

Indirect immunofluorescent staining of the microtubules in interphase and mitotic amoebae of the myxomycetePhysarum polycephalum

Summary The microtubules ofPhysarum amoebae have been decorated with rat antibodies against yeast tubulin. The indirect fluorescent staining observed in interphase amoebae and in flagellated amoebae is consistent with the three-dimensional reconstructions previously deduced from electron microscopic studies. Mitotic amoebae exhibit a pattern of fluorescence which is similar to that exhibited by mammalian cells and is consistent with the previous electron microscopic studies, except that we also observe pole-pole microtubule fibers during metaphase and anaphase and the presence of a typical midbody during cytokinesis. The various types of tripolar mitosis which are observed suggest that there is a regulatory mechanism allowing the formation of pseudo-bipolar mitotic apparatuses in amoebae possessing more than two mitotic centers during mitosis. The mitotic center, located in the middle of the centrosphere, is not fluorescent after staining of the monoasters induced with taxol suggesting the absence of tubulin in the mitotic center.     

Mitosis-specific monoclonal antibodies block cleavage in amphibian embryos

By microinjecting monoclonal antibodies that bind specifically to mitotic and meiotic cells of a variety of species, we studied the biological activity of antigens recognized by these antibodies. The antibodies recognize a family of phosphoprotein antigens that are found throughout the cytoplasm of mitotic cells and particularly at microtubule organizing centers, including centrosomes and kinetochores. Their binding is dependent on phosphorylation of the polypeptides. Immunoglobulins were introduced into Xenopus laevis and Rana pipiens oocytes or cleaving embryos using glass micropipettes. The ability of the antibody-injected oocytes to undergo mitosis or meiosis was compared with those injected with control mouse immunoglobulins. The antibodies failed to block chromosome condensation and germinal vesicle breakdown in progesterone-treated oocytes. However, functional mitotic spindles were not assembled in cleavage stage frog embryos injected with antibodies. In vitro, the binding of the antibodies to the antigens inhibited the dephosphorylation of the antigens by alkaline phosphatase. The antibody binding to the activated microtubule organizing centers (MTOC) seems to block not only the nucleation of microtubules and the organization of the mitotic spindle, but also the dephosphorylation of proteins associated with the MTOC that normally occurs at the mitosis-G1 transition.     

Overexpression of cyclin A in human HeLa cells induces detachment of kinetochores and spindle pole/centrosome overproduction

The combination of hydroxyurea (HU) and caffeine has been used for inducing kinetochore dissociation from mitotic chromosomes and for causing centrosome/spindle pole amplification. However, these effects on microtubule organizing centers (MTOCs) are limited to certain cell types. It was reasoned that if the biochemical differences in MTOC behavior between cells following HU treatment could be identified, then critical information concerning the regulation of these organelles would be obtained. During these studies, it was determined that cells from hamster, rat, and deer could be induced to enter mitosis with dissociated kinetochores and to synthesize centrosomes during arrest with HU, while cells from human and mouse could not. Comparisons between human HeLa cells and CHO cells determined that cyclin A levels were depressed in HeLa cells relative to CHO cells following HU addition. Overexpression of cyclin A in HeLa cells converted them to a cell type capable of detaching kinetochores from mitotic chromosomes. Ultrastructural analyses determined that the detached human kinetochores exhibited a normal plate-like morphology and appeared capable of associating with microtubules. In addition, HeLa cells overexpressing cyclin A also overproduced spindle poles during HU arrest, demonstrating that cyclin A activity also is important for centrosome replication during interphase. In summary, elevated cyclin A levels are important for the capacity of cells to be driven into mitosis by caffeine addition, for the ability of cells to progress to mitosis with detached kinetochores, and for centrosome/spindle pole replication.     

Germinal centers and the B-cell system

Summary The migration pattern of germinal center cells of the rabbit appendix was studied and compared with that of appendix dome cells, spleen cells, thymus cells and thoracic duct lymphocytes. To discriminate T-and B-cell migration pathways, normal or T-cell-depleted rabbits were used as donors. Cell suspensions were labeled in vitro with ³H-leucine followed by intravenous transfer. The migration of labeled cells in lymphoid organs was studied using autoradiography, particular attention being paid to the spleen of the recipient. B-cells from the appendix dome, spleen and thoracic-duct lymph migrate to primary follicles or the corona of secondary follicles via thymus-dependent areas of peripheral lymphoid organs. In contrast, a B-cell subpopulation from the germinal centers of the appendix migrates to the center of splenic primary follicles and into germinal centers. The migration of germinal center cells to splenic follicle centers is not enhanced by specific antigens. The migration properties of B-cells, possibly changing during differentiation, may be instrumental in the two types of immune reactions, i.e., plasma-cell reaction and germinal-center reaction.     

Germinal centers and the B-cell system

Summary Germinal centers of the rabbit appendix were studied for the presence of complement receptors, immunoglobulin and alkaline phosphatase. In popliteal lymph nodes, de novo-developing germinal centers were studied with respect to these markers up to 21 days after sheep red blood cell (SRBC)-stimulation. In addition, the possible presence of antigen (SRBC) receptor-bearing cells in these germinal centers was investigated.The results may be summarized as follows: 1) Germinal centers in the appendix as well as those in popliteal lymph nodes were rich in complement receptor-bearing cells. Complement-receptor density did not significantly change during a germinal-center reaction. 2) Immunoglobulins were present only at very low densities on the surface of lymphoid cells in the densely populated area of germinal centers. In germinal centers of popliteal lymph nodes lymphoid cells in the thinly populated area again showed higher densities. Immunoglobulins possibly complexed with antigen on the surface of follicular dendritic cells were not observed in the initial phase of a germinal center reaction. In contrast, in germinal centers of the appendix, immunoglobulin was present in excessive amounts throughout the thinly populated area, possibly complexed with antigen, which is also abundantly present. 3) Reticular staining patterns of alkaline phosphatase were present in the densely populated area, but absent in the thinly populated area of germinal centers in both appendix and popliteal lymph nodes. Primary follicles and young germinal centers were alkaline phosphatase-negative. 4) Antigen receptor-bearing cells were detected in germinal centers of popliteal lymph nodes as early as 5 days after SRBC-stimulation, reaching a maximum at day 10.In conclusion, with the present experimental approach, microenvironmental differences were shown between the densely populated area and the thinly populated area of germinal centers. However, no indication was obtained for a postulated maturation event of the lymphocytes within germinal centers, or for functional differences that may exist between germinal centers in the appendix and popliteal lymph nodes.     

Biochemical Differences between Staurosporine-Induced Apoptosis and Premature Mitosis

Apoptosis is morphologically related to premature mitosis, an aberrant form of mitosis. Staurosporine, a potent protein kinase inhibitor, induces not only apoptotic cell death in a wide variety of mammalian cells but also premature initiation of mitosis in hamster cells that are arrested in S phase by DNA synthesis inhibitors. Here we report on the biochemical differences between the two phenomena commonly caused by staurosporine. Rat 3Y1 fibroblasts that had been arrested in S phase with hydroxyurea underwent apoptosis by treatment with staurosporine, whereas S-phase-arrested CHO cells initiated mitosis prematurely when similarly treated with a low concentration of staurosporine. Chromosome condensation occurred in both apoptosis (3Y1) and premature mitosis (CHO). However, neither formation of mitotic spindles nor mitosis-specific phosphorylation of MPM-2 antigens was observed in apoptosis of 3Y1 cells, unlike premature mitosis of CHO cells. The p34^cdc2kinase activated in normal and prematurely mitotic cells remained inactive in the apoptotic cells, probably because the active cyclin B/p34^cdc2complex was almost absent in the S-phase-arrested 3Y1 cells. The absence of intracellular activation of p34^cdc2in apoptosis was confirmed by immunohistochemical analyses using a specific antibody raised against Ser⁵⁵-phosphorylated vimentin which is specifically phosphorylated by p34^cdc2during M phase. Furthermore, phosphorylation of histones H1 and H3, which is associated with mitotic chromosome condensation, did not occur in the apoptotic cells. These results indicate that the two phenomena, staurosporine-induced apoptosis and premature mitosis, are different in their requirement for p34^cdc2kinase activation and histone phosphorylation.     

The early postnatal development of the primary immune response in TNP-KLH-stimulated popliteal lymph node in the rat

Summary The popliteal lymph nodes were removed from young rats of various ages five days after a single immunization with TNP-KLH in the hind footpads. Cryostat sections of the lymph nodes were investigated by means of enzyme and immunohistochemical techniques at the light-microscopical level.The presence and localization of anti-TNP antibody-containing cells were examined using a new technique to visualize specific antibodies. Moreover, the development of the lymph nodes following exogenous antigenic stimulation was compared with that of unstimulated lymph nodes.Specific antibody-containing cells could not be found before day 15 after birth, in rats immunized at day 10. From that time these lymphoid cells were located primarily at the border between cortex and medulla. Younger popliteal lymph nodes showed only aspecific immunoglobulin-containing lymphoid cells. With age, the number of specific antibody-containing cells tended to increase. These cells were more mature, according to morphological criteria and were located nearer the medulla.The first primary follicles were seen at day 19, as was the case in unstimulated animals. The first secondary follicles, containing germinal centers, were detected at day 23, whereas in unstimulated popliteal lymph nodes they were never found.Trapping of immune complexes could not be demonstrated before day 33 after birth. The later appearance of this phenomenon might be a consequence of the techniques applied to demonstrate specific antibody-containing cells.Abbreviations PLN popliteal lymph node - FDC follicular dendritic cell - IDC interdigitating cell - HEV high endothelial venule - TNP trinitrophenyl - KLH keyhole limpet hemocyanin - PBS phosphate-buffered saline - GCPC germinal center precursor cell - sIg surface immunoglobulin - cIg cytoplasmic immunoglobulin     

Cell cycle-dependent localization of CHK2 at centrosomes during mitosis

Background

Centrosomes function primarily as microtubule-organizing centres and play a crucial role during mitosis by organizing the bipolar spindle. In addition to this function, centrosomes act as reaction centers where numerous key regulators meet to control cell cycle progression. One of these factors involved in genome stability, the checkpoint kinase CHK2, was shown to localize at centrosomes throughout the cell cycle.

Results

Here, we show that CHK2 only localizes to centrosomes during mitosis. Using wild-type and CHK2^?/? HCT116 human colon cancer cells and human osteosarcoma U2OS cells depleted for CHK2 with small hairpin RNAs we show that several CHK2 antibodies are non-specific and cross-react with an unknown centrosomal protein(s) by immunofluorescence. To characterize the localization of CHK2, we generated cells expressing inducible GFP-CHK2 and Flag-CHK2 fusion proteins. We show that CHK2 localizes to the nucleus in interphase cells but that a fraction of CHK2 associates with the centrosomes in a Polo-like kinase 1-dependent manner during mitosis, from early mitotic stages until cytokinesis.

Conclusion

Our findings demonstrate that a subpopulation of CHK2 localizes at the centrosomes in mitotic cells but not in interphase. These results are consistent with previous reports supporting a role for CHK2 in the bipolar spindle formation and the timely progression of mitosis.

     

Homing of germinal-center cells into germinal centers of lymph node via afferent lymphatics

Summary Affinity of lymphoid cells for the microenvironment of germinal centers (GC), as detectable in transfer experiments by rapid homing in spleen GC from the blood, is a capacity expressed by only a subset of lymphoid cells, in particular by those constituting a GC. However, when introduced into the blood stream, these cells do not home into GC of lymph nodes and gut-associated lymphoid tissues. To investigate further this homing inability for high endothelial venule (HEV)-containing lymphoid tissues, GC cells isolated from donor rabbit appendix were labeled in vitro with ³H-leucine and injected into an afferent lymph vessel of recipient popliteal lymph nodes. Draining lymph nodes were removed 15 min to 24 h after cell administration and prepared for radioautography. For reference, the migration of cells isolated from Peyer's patches and thoracic duct lymph was also studied. By use of appendix GC cells, large numbers of labeled cells were found to migrate into GCs of the outer cortex centripetally, i.e., from the subcapsular sinus through the lymphocyte corona into the GC proper. The same was observed for cells from Peyer's patches, although in smaller numbers. Thoracic duct lymphocytes were only localized in the lymphocyte corona and the deep cortex. Thus, appendix GC cells and a subpopulation of cells from Peyer's patches can reach lymph node GC, but only when administered intralymphatically. We conclude that cells expressing affinity for the GC microenvironment do so for both spleen and lymph node GC, but do not have the capacity to interact with the wall of HEV; its implication for the understanding of the dynamics of a GC reaction is discussed.Abbreviations GC germinal center - GCC germinal-center cells - AGCC appendix germinal-center cells - GCPC germinal-center precursor cells - GCSC germinal-center seeking cells - HEV high endothelial venules - SRBC sheep red blood cells - PP Peyer's patch - TDL thoracic duct lymphocytes - NCS newborn calf serum - PBS phosphate-buffered saline - PNA peanut agglutinin - LN lymph node - LC lymphocyte corona - DC deep cortex unit     

Effect of thymus cell injections on germinal center formation in lymphoid tissues of nude (thymusless) mice

Nude mice, partially backcrossed to Balb/c or DBA/2, were injected iv with 5 × 10⁷ thymus cells from the respective inbred strain. The response of these mice to immunization with Brucella abortus antigen was studied, with respect to both antibody production and the formation of germinal centers in their lymphoid tissues. The results were compared to those obtained with nude mice to which no thymus cells were given, as well as to Balb/c, DBA/2, or +/? litter mate controls.Nude mice formed less 19S as well as 7S antibody than did litter mate controls and completely lacked germinal centers in lymph nodes and gut-associated lymphoid tissue. Those nude mice which had been injected with thymus cells made a much better secondary response, both for 19S and for 7S antibody, and had active germinal centers in their lymph nodes as early as 3 wk after thymus cell injection. Intestinal lymphoid tissue in nude mice showed only slight reconstitution of germinal center activity several months after thymus cell injection and none at earlier times. Irradiated (3000 R) thymus cells appeared as effective as normal cells in facilitating germinal center appearance and 7S antibody production in the nude mice.     

The in vitro response of thymic lymphocytes of the pig to phytohemagglutinin

The response of thymic lymphocytes of the pig to phytohemagglutinin was studied with H³ thymidine in cultures, from 0–72 hours. At the beginning of the culture period 6–18% of lymphocytes were in DNA synthesis. during the first 24 hours a sharp decrease in the number of DNA synthesizing cells was observed in both pha and control cultures, although pha cultures consistently showed small but significantly greater numbers of DNA synthesizing cells. this was followed by a definite peak in DNA synthesis and mitotic response of a minority of the cells in pha cultures between 48–54 hours, whereas in control cultures activity ceased. in addition, a small proportion of the progeny of initially DNA synthesizing medium sized lymphocytes was apparently stimulated by pha and found in mitosis by 48 hours. It was concluded that the thymus contains a fraction of lymphocytes, not in the mitotic cycle, which are capable of being transformed by pha to mitotic activity. the data also suggests some stimulation of cells already in the mitotic cycle.     

Topography,ultrastructure and phagocytic capacity of avian lymph nodes

Summary The structure of the avian lymph node (ALN) is characterized by a thin capsule, thin lymphoreticular cords, and an absence of trabeculae. It is not possible to subdivide the ALN into cortex, paracortex and medulla, or to subdivide the system of sinuses into marginal, trabecular and medullary divisions. The lymphoreticular cords contain avian germinal centers (AGC) with B-lymphocytes and the area of T-lymphocytes.Postcapillary venules are responsible for the recirculation of lymphocytes. Sinus reticular cells do not exist in the ALN, but free macrophages are present. The phagocytic capacity of the macrophages was determined by injection of vital dyes (India ink, Berlin blue) and inoculation with Candida cells. Macrophages filled with markers migrate from the lymph sinuses into the lymphoreticular cords and further into the AGC. The mobility of the macrophages is remarkably lower after phagocytosis of Candida cells.This study is dedicated to Prof. Dr. Dr. h.c. Hugo Grau (Weilheim) with sincere appreciation and respect     

A study of lymphocyte subsets in human normal tonsil and lymph node

A series of T and B lymphocyte specific monoclonal antibodies was used to determine the localization of lymphocyte subpopulation in frozen and paraffin tissue sections of human normal tonsil and lymph node by means of immunocytochemical technique. In the paracortical and interfollicular area of tonsil and lymph node, most lymphocytes reacted with Leu 1, Leu 3 a, Leu 4 and OKT4. The numbers of Leu 2 a and OKT8 positive cells were rare in tissue. These cells were not only limited in paracortical area, they also appeared in considerable numbers in medullary cords of lymph nodes. Leu 2 a and OKT 8 positive cells decreased with prominent follicular hyperplasia of tonsils. In addition, substantial leu 3 a and Leu 4 cells were found in the germinal centers. This finding supports the importance of these lymphocyte subsets in regulation of human immune response. In the mantle zone of secondary follicles, the majority of lymphocytes were positive for OKB 2 and BA 1, whereas, the IgM positive cells were predominately observed in the cytoplasma and extracellular substance of B lymphocytes in the germinal centers, but the lymphocytes bearing sIgM were rarely observed. In the mantle zone, the IgM were frequently found on the surface of membrane of small lymphocytes, however, the staining intensity was much than that in the germinal centers.     

Functional analysis of phosphorylation of the mitotic centromere-associated kinesin by Aurora B kinase in human tumor cells

Mitotic centromere-associated kinesin (MCAK) is the best characterized member of the kinesin-13 family and plays important roles in microtubule dynamics during mitosis. Its activity and subcellular localization is tightly regulated by an orchestra of mitotic kinases, such as Aurora B. It is well known that serine 196 of MCAK is the major phosphorylation site of Aurora B in Xenopus leavis extracts and that this phosphorylation regulates its catalytic activity and subcellular localization. In the current study, we have addressed the conserved phosphorylation site serine 192 in human MCAK to characterize its function in more depth in human cancer cells. Our data confirm that S192 is the major phosphorylation site of Aurora B in human MCAK and that this phosphorylation has crucial roles in regulating its catalytic activity and localization at the kinetochore/centromere region in mitosis. Interfering with this phosphorylation leads to a delayed progression through prometa- and metaphase associated with mitotic defects in chromosome alignment and segregation. We show further that MCAK is involved in directional migration and invasion of tumor cells, and interestingly, interference with the S192 phosphorylation affects this capability of MCAK. These data provide the first molecular explanation for clinical observation, where an overexpression of MCAK was associated with lymphatic invasion and lymph node metastasis in gastric and colorectal cancer patients.     

Ultrastructural analysis of HNK-1+ cells in human peripheral blood and lymph nodes

HNK-1 positive (HNK-1+) cells in human peripheral blood and lymph nodes were comparatively analysed by means of immunohistochemistry and immunoelectron microscopy. In peripheral blood, the HNK-1+ cells were grouped into large granular lymphocytes (LGLs), small lymphocytes and intermediate forms, all of which had many fine cytoplasmic processes. Except for smooth-surfaced lymphocytes, they could not be distinguished from helper/inducer T (OKT4/Leu3a) cells and suppressor/cytotoxic T (OKT8/Leu2a) cells. In double staining, HNK-1+T3- cells and HNK-1+T3+ cells could not be clearly distinguished in terms of morphology, although the former contained many LGLs. The HNK-1+ cells in the lymph nodes accumulated in the light zones of the germinal centers (GCs). These cells were small to medium-sized lymphocytes with few electron-dense granules and exclusively co-expressed helper/inducer T cell antigens (HNK-1+T4+). Their cytoplasmic projections were interwoven with those of the follicular dendritic cells which trap immune complexes for a long duration. These configurations suggest that HNK-1+T4+ cells in GCs are engaged in an immunological regulation of germinal center cells. On the other hand, large blastic HNK-1+ cells were scattered outside the GCs and some of them were in the process of mitosis. Furthermore, HNK-1+LGL-like cells with a few large electron-dense granules were rarely seen. These observations indicate that the HNK-1+ cells in the lymph nodes may proliferate outside GCs and differentiate into LGLs with a strong natural killer function.     

Amphibian oocyte maturation induced by extracts of Physarum polycephalum in mitosis

The orderly progression of eukaryotic cells from interphase to mitosis requires the close coordination of various nuclear and cytoplasmic events. Studies from our laboratory and others on animal cells indicate that two activities, one present mainly in mitotic cells and the other exclusively in G1-phase cells, play a pivotal role in the regulation of initiation and completion of mitosis, respectively. The purpose of this study was to investigate whether these activities are expressed in the slime mold Physarum polycephalum in which all the nuclei traverse the cell cycle in natural synchrony. Extracts were prepared from plasmodia in various phases of the cell cycle and tested for their ability to induce germinal vesicle breakdown and chromosome condensation after microinjection into Xenopus laevis oocytes. We found that extract of cells at 10-20 min before metaphase consistently induced germinal vesicle breakdown in oocytes. Preliminary characterization, including purification on a DNA-cellulose affinity column, indicated that the mitotic factors from Physarum were functionally very similar to HeLa mitotic factors. We also identified a number of mitosis-specific antigens in extracts from Physarum plasmodia, similar to those of HeLa cells, using the mitosis-specific monoclonal antibodies MPM-2 and MPM-7. Interestingly, we also observed an activity in Physarum at 45 min after metaphase (i.e., in early S phase since it has no G1) that is usually present in HeLa cells only during the G1 phase of the cell cycle. These are the first studies to show that maturation-promoting factor activity is present in Physarum during mitosis and is replaced by the G1 factor (or anti-maturation-promoting factor) activity in a postmitotic stage. A comparative study of these factors in this slime mold and in mammalian cells would be extremely valuable in further understanding their function in the regulation of eukaryotic cell cycle and their evolutionary relationship to one another.