The mouse homeobox gene, S8, is expressed during embryogenesis predominantly in mesenchyme.

The murine S8 gene, originally identified by Kongsuwan et al. [EMBO J. 7(1988)2131-2138] encodes a homeodomain which resembles those of the paired family. We studied the expression pattern during mid-gestation embryogenesis of S8 by in situ hybridization. Expression was detected locally in craniofacial mesenchyme, in the limb, the heart and the somites and sclerotomes all along the axis, and was absent from the central and peripheral nervous system, splanchnopleure, and endodermal derivatives. This pattern differs considerably from that of most previously described homeobox containing genes. By genetic analysis, the gene was located on chromosome 2, about 20 cM from the HOX-4 cluster.     

Organization of DNA replication in Physarum polycephalum. Attachment of origins of replicons and replication forks to the nuclear matrix.

We have investigated the attachment of the DNA to the nuclear matrix during the division cycle of the plasmodial slime mold Physarum polycephalum. The DNA of plasmodia was pulse labelled at different times during the S phase and the label distribution was studied by graded DNase digestion of the matrix-DNA complexes prepared from nuclei isolated by extraction with 2 M NaCl. Pulse labelled DNA was preferentially recovered from the matrix bound residual DNA at any time of the S phase. Label incorporated at the onset of the S phase remained preferentially associated with the matrix during the G2 phase and the subsequent S phase. The occurrence of the pulse label in the matrix associated DNA regions was transiently elevated at the onset of the subsequent S phase. Label incorporated at the end of the S phase was located at DNA regions which, in the G2 phase, were preferentially released from the matrix by DNase treatment. From the results and previously reported data on the distribution of attachment sites it can be concluded that origins of replicons or DNA sites very close to them are attached to the matrix during the entire nuclear cycle. The data further indicate that initiations of DNA replication occur at the same origins in successive S phases. Replicating DNA is bound to the matrix, in addition, by the replication fork or a region close to it. This binding is loosened after completion of the replication.     

B lymphocyte-associated antigens on terminal deoxynucleotidyl transferase-positive cells and pre-B cells in bone marrow of the rat

To investigate early stages of B lymphocytopoiesis in rat bone marrow (BM) before the expression of surface IgM (s mu), the populations of cytoplasmic mu-chain-positive (c mu+) pre-B cells and terminal deoxynucleotidyl transferase-positive (TdT+) cells were studied by double immunofluorescence microscopy. B lymphocytes that were s mu+ constituted 5%, c mu+s mu- pre-B cells 23%, and TdT+ cells 4% of nucleated cells in the BM of juvenile rats. TdT+ and pre-B cells ranged between 7 and 17 microns in diameter. TdT+ cells were slightly larger, with a modal diameter of 10.5 microns against 9 microns for pre-B cells. mu-Chains were absent from nearly all TdT+ cells. Their surface antigenic phenotype was studied by using a panel of mouse monoclonal antibodies (MAb) to rat B lymphocyte-associated antigens (Ig, Ia, and others) and T lymphocyte-associated antigens. Both pre-B cells and TdT+ lacked surface Ig and Ia but carried most of the other B lymphocyte-associated antigens analyzed. TdT+ and pre-B cells lacked those antigens found only on the T lineage. By using MAb HIS24 (detecting a non-Ig/Ia B lymphocyte-associated antigen) and fluorescence-activated cell sorting, TdT+ and pre-B cells were highly enriched. The results show that most TdT+ cells in rat BM are mu- but demonstrate strong similarity with pre-B cells in surface antigenic phenotype. Therefore, as suggested for man, a major proportion of rat BM TdT+ cells may be B lineage-cells before mu heavy chain gene expression.     

An in situ study of B-lymphocytopoiesis in rat bone marrow. Topographical arrangement of terminal deoxynucleotidyl transferase-positive cells and pre-B cells

To understand bone marrow (BM) as a site of B-lymphocytopoiesis, insight into the topographical arrangement of developing B cells and their relationships to the microenvironment in vivo is required. To study the spatial distribution of B lymphocyte progenitors defined by intracellular markers (cytoplasmic mu H chain and nuclear terminal deoxynucleotidyl transferase (TdT], we developed a technique to cut frozen femurs of rat, yielding cross-sections with intact subendosteal and central marrow. By using (double) immunofluorescence staining techniques we located pre-B and TdT+ cells, and IgM+ B cells in those sections. Of the B cells present in BM, one-third was accumulated in the lumen of blood sinuses. The rest were in the BM parenchyma, as were virtually all pre-B and TdT+ cells. The subendosteal area was twice as rich in pre-B and TdT+ cells as the central area, and within the subendosteal area a profound positive gradient toward the bone was evident. B cells showed an equal distribution over the center and the periphery of the BM. The distribution patterns of B lineage cells in the BM parenchyma were analyzed and shown in part to deviate from random distribution. Additional study of clonal development and microenvironmental factors in hematopoiesis will have to clarify the underlying mechanisms for the observed distribution patterns of B cell precursors in BM.     

Hatching in the pike Esox lucius L.: Evidence for a single hatching enzyme and its immunocytochemical localization in specialized hatching gland cells

Antibodies against purified hatching enzyme (HE) from the pike, Esox lucius L., have been used to examine different aspects of the presence of the enzyme in the ontogeny of this teleostean fish. Immunochemical analysis indicates that the two proteolytic enzymes which occur in the hatching medium arise from a single protease, HE itself. The second proteolytic fraction found in gel filtration of hatching medium could be a heterogeneous population of complexes of HE with digestion fragments of its natural substrate, the zona radiata. Immunofluorescence microscopy by means of anti-HE antibodies demonstrates that HE is localized in the so-called hatching gland cells (HGCs). The HGCs in pike appear as oval to round cells 10–15 μm in diameter containing granules of 1.5–2.3 μm. They are found interspersed between the periderm and the presumptive epidermis. The number of HGCs and their granule content increase significantly until the 35-somite stage to reach about 1200 and 30, respectively. From then on these numbers do not change until hatching in the 66-somite stage. The distribution of the HGCs over the embryo also changes, probably since HGC precursors in the yolk sac differentiate to HGCs later than their counterparts in the head region. The immunocytochemical procedure further shows that HE can be detected from the 10-somite stage on. Discrete hatching gland remnant bodies, phagocytized by epidermal cells, are observed in larval stages until 3–7 days after emergence of the embryo.     

High-level expression of recombinant IgG in the human cell line per.c6

The number of therapeutic monoclonal antibodies in production is expected to rise rapidly in the next few years. As a result, there is much focus on the optimization of antibody expression platforms. Several issues are important including the speed of transition from bench to manufacturing, yield of IgG, and quality (particularly of the glycan structures present on immunoglobulins). We have characterized the human cell line PER.C6 for its ability to produce recombinant IgG. Production yields are still being optimized, but in nonfed batch culture, PER.C6 is able to grow to a cell density of 5 x 10(6) cells/mL and produce 300-500 mg/L IgG; this is likely to increase significantly in fed batch cultures. The generation of antibody-producing cell lines is fast, as rounds of amplification of inserted genes are not required for high production yields. The gene copy number of inserted genes is in the region of 1-10 copies per genome. In addition, PER.C6 is a human cell line, and so does not add glycans, which are immunogenic in humans. A core fucose molecule is essentially always present, and galactose residues are present at a physiological level (0, 1, and 2 galactose residues per glycan are present at a ratio of 1:2:1). No hybrid or high-mannose structures are seen.     

Virus Maturation by Budding

Enveloped viruses mature by budding at cellular membranes. It has been generally thought that this process is driven by interactions between the viral transmembrane proteins and the internal virion components (core, capsid, or nucleocapsid). This model was particularly applicable to alphaviruses, which require both spike proteins and a nucleocapsid for budding. However, genetic studies have clearly shown that the retrovirus core protein, i.e., the Gag protein, is able to form enveloped particles by itself. Also, budding of negative-strand RNA viruses (rhabdoviruses, orthomyxoviruses, and paramyxoviruses) seems to be accomplished mainly by internal components, most probably the matrix protein, since the spike proteins are not absolutely required for budding of these viruses either. In contrast, budding of coronavirus particles can occur in the absence of the nucleocapsid and appears to require two membrane proteins only. Biochemical and structural data suggest that the proteins, which play a key role in budding, drive this process by forming a three-dimensional (cage-like) protein lattice at the surface of or within the membrane. Similarly, recent electron microscopic studies revealed that the alphavirus spike proteins are also engaged in extensive lateral interactions, forming a dense protein shell at the outer surface of the viral envelope. On the basis of these data, we propose that the budding of enveloped viruses in general is governed by lateral interactions between peripheral or integral membrane proteins. This new concept also provides answers to the question of how viral and cellular membrane proteins are sorted during budding. In addition, it has implications for the mechanism by which the virion is uncoated during virus entry.     

Disulfide bonds in folding and transport of mouse hepatitis coronavirus glycoproteins.

We have analyzed the effects of reducing conditions on the folding of the spike (S) protein and on the intracellular transport of the membrane (M) protein of the mouse hepatitis coronavirus. These proteins differ in their potential to form disulfide bonds in the lumen of the endoplasmic reticulum (ER). Intrachain disulfide bonds are formed in the S protein but not in M, which was demonstrated in a pulse-chase experiment by analyzing the viral proteins under nonreducing conditions. To reduce disulfide bonds in vivo, we added dithiothreitol (DTT) to the culture medium of mouse hepatitis coronavirus-infected cells following a procedure recently described by Braakman et al. (I. Braakman, J. Helenius, and A. Helenius, EMBO J. 11:1717-1722, 1992). Short exposure to DTT resulted in the complete reduction of newly synthesized S protein and affected its conformation as judged by the change in mobility in nonreducing gels and by the loss of recognition by a conformation-specific monoclonal antibody. Using this antibody in an immunofluorescence assay, we monitored the reducing effect of DTT in situ. DTT was found to initially affect only the S protein present in the ER; also, after longer treatment, the remaining signal also gradually disappeared. In contrast, folding and transport of the M protein were not inhibited by DTT. Under reducing conditions, M was transported efficiently to the trans side of the Golgi complex, indicating that cellular processes such as ER-to-Golgi transport, O-glycosylation, and Golgi retention were unaffected. In the presence of DTT, the M protein even moved at an increased rate to the Golgi complex, which is probably because of its failure to interact with unfolded S protein. The effects of in vivo reduction were reversible. When DTT was removed from pulse-labeled cells, the S protein folded posttranslationally and aberrantly; during its oxidation, most of S now transiently aggregated into large disulfide-linked complexes from which subsequently folded S molecules dissociated.     

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.     

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