Adenovirus type 2 expresses fiber in monkey-human hybrids and reconstructed cells.

Adenovirus type 2 protein expression was measured by indirect immunofluorescence in monkey-human hybrids and in cells reconstructed from monkey and human cell karyoplasts and cytoplasts. Monkey-human hybrid clones infected with adenovirus type 2 expressed fiber protein, whereas infected monkey cells alone did not. Hybrids constructed after the parental monkey cells were infected with adenovirus type 2 demonstrated that fiber synthesis in these cells could be rescued by fusion to uninfected human cells. Thus, human cells contain a dominant factor that acts in trans and overcomes the inability of monkey cells to synthesize fiber. Cells reconstructed from infected human karyoplasts and monkey cytoplasts expressed fiber, whereas cells reconstructed from infected monkey karyoplasts and human cytoplasts did not. These results are consistent with the hypothesis that the block to adenovirus replication in monkey cells involves a nuclear event that prevents the formation of functional mRNA for some late viral proteins including fiber polypeptide. Furthermore, they suggest that the translational apparatus of monkey cells is competent to translate functional fiber mRNA synthesized in human cells.     

Radiolabeling rhesus monkey CD34+ hematopoietic and mesenchymal stem cells with 64Cu-pyruvaldehyde-bis(N4-methylthiosemicarbazone) for microPET imaging

Noninvasive positron emission tomography (PET) provides a potential method for in vivo tracking of radiolabeled cells. The goal of this study was to assess the potential toxicity of 64Cu-pyruvaldehyde-bis(N4-methylthiosemicarbazone) (PTSM) on rhesus monkey CD34+ hematopoietic and mesenchymal stem cells in vitro in preparation for developing imaging protocols posttransplantation. CD34+ hematopoietic cells were radiolabeled with 0 to 40 microCi/mL 64Cu-PTSM and viability and colony formation were assessed. Rhesus monkey mesenchymal stem cells (rhMSCs) were placed in culture postradiolabeling for assessments of growth and differentiation toward adipogenic, osteogenic, and chondrogenic lineages. The results indicated that CD34+ cells radiolabeled with 20 microCi/mL and rhMSCs radiolabeled with 10 microCi/mL 64Cu-PTSM did not result in adverse effects on growth or differentiation. Nonradioactive copper was also evaluated and showed that the presence of copper was not harmful to the cells. CD34+ cells and rhMSCs radiolabeled with the optimized concentrations of 20 and 10 microCi/mL, respectively, were also assessed using the microPET scanner. Studies showed that a minimum of 2.50x10(4) CD34+ cells (1.1 pCi/cell) and 6.25x10(3) rhMSCs (4.4 pCi/cell) could be detected. These studies indicate that CD34+ hematopoietic cells and rhMSCs can be safely radiolabeled with 64Cu-PTSM without adverse cellular effects.     

Physical separation of colony stimulating cells from in vitro colony forming cells in hemopoietic tissue

Hemopoietic colony formation in agar occurred spontaneously in mass cultures of marrow cells obtained from a number of species (guinea pig, rat, lamb, rabbit, pig, calf, human and Rhesus monkey). This contrasted with the observation that colony formation by mouse bone marrow exhibited an absolute requirement for an exogenous source of a colony stimulating factor. Analysis of spontaneous colony formation in Rhesus monkey marrow cultures revealed the presence of a cell type in hemopoietic tissue, capable of elaborating colony stimulating factor when used to condition media or as feeder layers. Equilibrium density gradient centrifugation separated colony stimulating cells from in vitro colony forming cells in monkey bone marrow. Separation studies on spleen, blood and marrow characterized the stimulating cells as of intermediate density, depleted or absent in fractions enriched for cells of the granulocytic series and localized in regions containing lymphocytes and monocytes. Adherence column separation of peripheral blood leukocytes showed the stimulating cells to be actively adherent, unlike the majority of lymphocytes, and combined adherence column and density separation indicated that stimulating cells were present in hemopoietic tissue within the population of adherent lymphocytes or monocytes.     

Effect of tunicamycin on cell fusion induced by Mason-Pfizer monkey virus.

Mason-Pfizer monkey virus, a D-type retrovirus, has been shown to induce multinucleate cell (syncytium) formation or cell fusion in several normal primate cells. A series of experiments has been carried out to examine whether a glycosylated "fusion-inducing" product is responsible for this biological property of Mason-Pfizer monkey virus. Treatment of rhesus monkey fetal lung cells with different concentrations of tunicamycin, a potent inhibitor of glycosylation, during infection with Mason-Pfizer monkey virus had no effect on cell fusion even though up to 5 micrograms of the drug per ml was tested. Furthermore, no significant effect on the extent of syncytium formation in rhesus monkey fetal lung cells was observed when the time of addition or duration of treatment with this inhibitor was varied. Nevertheless, tunicamycin was very effective in blocking glycosylation in rhesus cells since virions produced in the presence of this drug completely lacked gp70 and gp20, the two structural glycoproteins of Mason-Pfizer monkey virus. These non-glycosylated virus particles produced in the presence of tunicamycin were noninfectious as determined by a protein A binding assay and were unable to induce syncytium formation when assayed on rhesus cells. These results indicate that glycosylation of the fusion-inducing product is not required for multinucleate cell formation induced by Mason Pfizer monkey virus.     

Cell sources of liver development

The work is devoted to consequent expression of different cell types' protein markers such as vimentin, desmin, cytokeratins 7, 18, 19, stem cell markers CD34 and Bcl-2 at early stages of human prenatal development. Desmin was revealed in sinusoidal liver cells on 3.5-12 weeks of gestation, in mesenchymal cells of ventral mesentery and hepatoblasts on the 4-7 accordingly. During hepatic period of blood formation such desmin positive sinusoidal cells were found to be located close to blood cells. So called "cholangio-" cytokeratins 7 and 19 showed different expression, the first one was found only in cholangiocytes, while cytokeratin 19 existed in hepatoblasts as well until week 15-16 of prenatal development. Mesenchymal cells of ventral mesentery are positive for cytokeratins 18 and 19 even brighter than hepatoblasts in the 4-7 weeks of gestation. Bcl-2 expression was seen in the same periods in most sinusoidal and mesenchymal cells of ventral mesentery. CD34 positive cells are strongly depicted in liver sinusoids from 4th until 9th weeks of gestation, but probably they are not a source of hepatocytes' development in embryonic ontogenesis. Ventral mesentery mesenchyme was negative for this very marker. These results let us suppose that hepatocytes and cholangiocytes may develop from quite different embryonic sources: cholangyocytes grow exceptionally from duodenum epithelial cells, while there is a strong possibility that hepatoblasts formation occurs with participation of mesenchymal cells.     

Appearance of hair follicle-inducible mesenchymal cells in the rat embryo

Rat vibrissa follicle morphogenesis starts around 13 days of gestation. By day 14 mesenchymal cells have already aggregated as 'condensations' beneath the initial hair bud. Some of the mesenchymal cells will form a dermal papilla, having profound effects on hair follicle formation. The appearance of follicle-inducing mesenchymal cells in the process of vibrissa follicle development was examined. Mesenchymal cells were isolated from the developing site of vibrissa follicles at 13 days or at later stages and amplified in mass culture, harvested and transplanted in association with the epithelium. It was demonstrated that 13-day mesenchymal cells did not induce any hair bulbs but those from 14 days or later stages could induce hair-producing new bulbs or new follicles depending on the association with the follicle epithelium or with the glabrous sole epidermis of the adult rats, respectively. Further, clones having hair bulb-inducing ability were obtained from 14- and 15-day mass-cultured mesenchymal cells. Based on these and other results, it was concluded that mesenchymal cells having follicle-inducing ability are present at least by 14 days in the future whisker pad region. This suggests that the differentiation of the dermal papilla cells must start before the initial hair bud stage.     

Dissecting coronary angiogenesis: 3D co-culture of cardiomyocytes with endothelial or mesenchymal cells

In embryogenesis, coronary blood vessels are formed by vasculogenesis from epicardium-derived progenitors. Subsequently, growing or regenerating myocardium increases its vasculature by angiogenesis, forming new vessels from the pre-existing ones. Recently, cell therapies for myocardium ischemia that used different protocols have given promising results, using either extra-cardiac blood vessel cell progenitors or stimulating the cardiac angiogenesis. We have questioned whether cardiomyocytes could sustain both vasculogenesis and angiogenesis. We used a 3D culture model of tissue-like spheroids in co-cultures of cardiomyocytes supplemented either with endothelial cells or with bone marrow-derived mesenchymal stroma cells. Murine foetal cardiomyocytes introduced into non-adherent U-wells formed 3D contractile structures. They were coupled by gap junctions. Cardiomyocytes segregated inside the 3D structure into clumps separated by connective tissue septa, rich in fibronectin. Three vascular endothelial growth factor isoforms were produced (VEGF 120, 164 and 188). When co-cultured with human umbilical cord endothelial cells, vascular structures were produced in fibronectin-rich external layer and in radial septa, followed by angiogenic sprouting into the cardiomyocyte microtissue. Presence of vascular structures led to the maintenance of long-term survival and contractile capacity of cardiac microtissues. Conversely, bone marrow mesenchymal cells formed isolated cell aggregates, which progressively expressed the endothelial markers von Willebrand's antigen and CD31. They proceeded to typical vasculogenesis forming new blood vessels organised in radial pattern. Our results indicate that the in vitro 3D model of cardiomyocyte spheroids provides the two basic elements for formation of new blood vessels: fibronectin and VEGF. Within the myocardial environment, endothelial and mesenchymal cells can proceed to formation of new blood vessels either through angiogenesis or vasculogenesis, respectively.     

Basement Membrane Formation in Transfilter Tooth Culture and Its Relation to Odontoblast Differentiation

The mesenchymal cells of the developing tooth differentiate into odontoblasts as a result of an epithelio-mesenchymal interaction. Odontoblast differentiation was studied in vitro by cultivating dental mesenchyme and epithelium with interposed filters. Separation of the two components by enzyme treatment resulted in removal of the basement membrane. When the epithelium was grown alone, or transfilter from killed lens capsule, the basement membrane was not restored. Transfilter cultivation with dental mesenchyme resulted in basement membrane formation, but only if the filter pores allowed penetration of cytoplasmic processes. Hence, a close association between the epithelial and the mesenchymal cells seems to be a prerequisite for the restoration of the basement membrane. Differentiation of odontoblasts took place only in explants in which a basement membrane was formed. Differentiation did not occur when contact of the mesenchymal cells with the basement membrane was prevented by small pore size filters. Further experiments demonstrating an intact basement membrane suggested that membrane contacts between the epithelial and the mesenchymal cells are not needed for odontoblast differentiation. Hence, we suggest that differentiation of odontoblasts is triggered via contact of the mesenchymal cells with the basement membrane.     

Urethral seam formation and hypospadias

Knowledge of the formation of the normal male urethra may elucidate the etiology of hypospadias. We describe urethral formation in the mouse, show the similarities and relevance to human urethral development, and introduce the concept of the epithelial seam formation and remodeling during urethral formation. Three mechanisms may account for epithelial seam formation: (1) epithelial-mesenchymal transformation similar to that described in the fusion of the palatal shelves, (2) apoptosis, and/or (3) tissue remodeling via cellular migration. Urethral development in the embryonic mouse (14-21 days of gestation) was compared with urethral formation in embryonic human specimens (8-16 weeks of gestation) by using histology, immunohistochemistry, and three-dimensional reconstruction. The urethra forms by fusion of the epithelial edges of the urethral folds, giving a midline epithelial seam. The epithelial seam is remodeled via cellular migration into a centrally located urethra and ventrally displaced remnant of epithelial cells. The epithelial seam is remodeled by narrowing approximately at its midpoint, with subsequent epithelial migration into the urethra or penile skin. The epithelial cells are replaced by mesenchymal cells. This remodeling seam displays a narrow band (approximately 30 microns wide) of apoptotic activity corresponding to the mesenchymal cells and not to epithelial cells. No evidence was seen of the co-expression of cytokeratin and mesenchymal markers (actin or vimentin). Urethral seam formation occurs in both the mouse and the human. Our data in the mouse support the hypothesis that seam transformation occurs via cellular migration and not by epithelial mesenchymal transformation or epithelial apoptosis. We postulate that disruption of epithelial fusion remodeling, and cellular migration leads to hypospadias.     

Purmorphamine enhances osteogenic activity of human osteoblasts derived from bone marrow mesenchymal cells

Purmorphamine is a novel small molecule with osteogenesis-inducing activity in multipotent mesenchymal progenitor cells, but there has been no evaluation of its effect on human cells to date. The aim of this study was to investigate the induction of osteogenic activity by purmorphamine in human osteoblasts differentiated from bone marrow mesenchymal cells. Cells were cultured in 24-well plates at a density of 2x10(4)/well in medium containing 1, 2 or 3 microM purmorphamine, or vehicle. At 7, 14 and 21 days, cell proliferation, viability, and alkaline phosphatase (ALP) activity were evaluated. Bone-like nodule formation was evaluated at 21 days. Purmorphamine did not affect cell proliferation or viability, but increased ALP activity and bone-like nodule formation. These results indicate that events related to osteoblast differentiation, including increased ALP activity and bone-like nodule formation, are enhanced by purmorphamine.     

人和猴T淋巴细胞表面TRBC受体及其配体不同于E2分子和CD2的配体

CD2 (E receptor, LFA-3 receptor) and E2 molecules (Bernard, 1988) on human T lymphocytes, CD58 (LFA-3, lymphocyte function associated antigen 3) on human erythrocytes and S14,S42,S110-220 molecules (Bernard, 1987) of sheep erythrocytes are involved in rosette formation of human T lymphocytes with human or sheep erythrocytes. Rosette formation of human and macaque pan-T lymphocytes with tree shrew (Tupaia belangeri) red blood cells (TRBC) (TRBC rosette) has shown different physicochemical properties from that of rosette formation with sheep red blood cells (E rosette) (Ben, 1985). CD2, CD3/TCR complex, CD5, CD6, and CD7 are not involved in TRBC rosette formation (Zheng, 1990). In order to know whether E2, LFA-3,S14,S42 and S110-220 molecules are involved in TRBC rosette formation or human and macaque T lymphocytes, rosette inhibition and antigenic modulation or co-modulation were performed with relevant monoclonal antibodies (McAbs), and hemolytic assay and slide agglutination were also conducted. TRBC rosette formation of human and rhesus monkey PBL was not blocked by E2 McAb (inhibition rate 2.8% and 2.1%, respectively). In contrast, human E rosette formation was obviously blocked at inhibition rate of 49.8% and macaque E rosette formation was slightly inhibited (13.3%). The modulation or co-modulation of E2 molecule with E2 McAb did not affect human TRBC rosette formation. Similar results were shown in rosette formation inhibition of Jurkat cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

恒河猴骨髓间质干细胞的体外分离培养及形态学特征分析(英文)

探索恒河猴骨髓间质干细胞(MSC)的体外分离培养方法,为其应用提供实验基础。取恒河猴骨髓细胞悬液,经梯度离心去除大部分血细胞,取含有MSC的中间单核细胞层,在含10%胎牛血清及1ng/mL碱性成纤维细胞生长因子的L-DMEM中培养扩增,并不断换液去除杂细胞,经过18d的原代培养,获得呈致密单层生长的MSC,其形态为较规则的长梭形细胞,排列有方向性,呈现一定的漩涡状、辐射状生长趋势。将原代细胞以1∶2传代,传代培养后期,细胞增殖速度逐渐变缓,细胞形态逐渐出现三角形、多边形及扁平宽大形等不规则形态。结果显示,恒河猴骨髓间质干细胞可在体外进行传代培养,但需进一步优化其培养条件。     

调控软骨形成的信号通路及相关因子在骨髓间充质干细胞骨向分化中的作用*

骨髓间充质干细胞是一类具有自我复制和多向分化潜能的成体干细胞,可以通过定向诱导分化为成骨细胞、软骨细胞、脂肪细胞等,是目前骨再生医学和细胞治疗研究最多的理想种子细胞。在骨缺损的修复过程中,骨髓间充质干细胞内成软骨相关基因表达升高进而分化为软骨细胞,后期随着成骨细胞和破骨细胞的形成及血管长入,软骨基质逐步降解并被骨基质所替换。软骨细胞参与了骨缺损前期的修复过程,调控软骨形成的信号通路及相关因子不仅调控骨髓间充质干细胞成软骨细胞分化,同时在成骨细胞分化过程中也发挥着重要的作用。对调控软骨形成的信号通路及相关因子在骨髓间充质干细胞骨向分化中的调控作用和研究现状进行了总结,以期为临床寻找更好的治疗骨缺损的方法提供理论依据和研究方向。     

Analyses of deoxycytidylate deaminase molecular forms in human-mouse and monkey-mouse somatic cell hybrids

Disc polyacrylamide gel electrophoresis (disc PAGE) analyses have revealed that mouse, human, and monkey cytosol deoxycytidylate (dCMP) deaminases differ in electrophoretic mobility, so that mixtures of mouse and human, mouse and monkey, and human and monkey enzymes can be separated. To learn whether the genes for dCMP deaminase and thymidine (dT) kinase are genetically linked, disc PAGE analyses of cytosol fractions from human-mouse and monkey-mouse somatic cell hybrids were carried out. The interspecific somatic cell hybrids were derived from the fusion of cytosol dT kinase deficient mouse cells with cytosol dT kinase-positive human and monkey cells: they contained mostly mouse chromosomes and a few primate chromosomes, including the determinant for primate cytosol dT kinase. The disc PAGE analyses demonstrated that the human-mouse and monkey-mouse somatic cell hybrids contained a dCMP deaminase activity with an electrophoretic mobility characteristic of mouse dCMP deaminase. Enzymes with electrophoretic mobilities characteristic of human and monkey dCMP deaminases were not demonstrable. These findings suggest that primate cytosol dT kinase and dCMP deaminase are coded on different chromosomes, or that the formation in hybrid cells of an active primate dCMP deaminase is suppressed. Chick-mouse somatic cell hybrids containing chick but not mouse cytosol dT kinase were also analyzed. The chick-mouse hybrid cells contained cytosol dCMP deaminase activity, but it was not possible to establish whether the enzyme was of murine or avian origin because of the similarity in electrophoretic mobility between the chick and mouse enzymes. Human and mouse cells contained low levels of mitochondrial dCMP deaminase activity. In contrast to dT kinase isozymes, however, mitochondrial and cytosol dCMP deaminases were electrophoretically indistinguishable.This investigation was aided by Grant Q-163 from the Robert A. Welch Foundation and by USPHS Grants CA-06656-12 and 1-K6-AI 2352 from the National Cancer Institute and the National Institute of Allergy and Infectious Diseases.     

菲立磁标记食蟹猴骨髓间充质干细胞的脑内移植示踪研究

中枢神经系统损伤后的再生修复问题一直是神经科学领域关注的重点之一,骨髓间充质干细胞移植治疗拓宽了人类中枢神经系统损伤的治疗前景,而非侵入性的磁共振成像能活体追踪移植细胞,评价移植效果。应用菲立磁标记食蟹猴骨髓来源的间充质干细胞,在脑立体定位仪引导下,自体脑内移植。结果显示,菲立磁标记间充质干细胞的有效率高达90%以上,移植区磁共振影像呈明显的低信号改变。标记的间充质干细胞移植后在脑内存活,并向周围的脑实质内迁移。移植8周后,发现移植细胞通过血管向对侧脑部迁移,但并未发现移植细胞向神经细胞分化。这些结果提示,菲立磁可用于标记、追踪脑内移植的食蟹猴骨髓间充质干细胞,标记的移植细胞可在脑内存活、迁移。     

CD271 as a marker to identify mesenchymal stem cells from diverse sources before culture

Mesenchymal stem cells, due to their characteristics are ideal candidates for cellular therapy. Currently, in culture these cells are defined by their adherence to plastic, specific surface antigen expression and multipotent differentiation potential. However, the in vivo identification of mesenchymal stem cells, before culture, is not so well established. Pre-culture identification markers would ensure higher purity than that obtained with selection based on adherence to plastic. Up until now, CD271 has been described as the most specific marker for the characterization andpurification of human bone marrow mesenchymal stem cells. This marker has been shown to be specifically expressed by these cells. Thus, CD271 has been proposed as a versatile marker to selectively isolated and expand multipotent mesenchymal stem cells with both immunosuppressive and lymphohematopoietic engraftment-promoting properties. This review focuses on this marker, specifically on identification of mesenchymal stem cells from different tissues. Literature revision suggests that CD271 should not be defined as a universal marker to identify mesenchymal stem cells before culture from different sources. In the case of bone marrow or adipose tissue, CD271 could be considered a quite suitable marker; however this marker seems to be inadequate for the isolation of mesenchymal stem cells from other tissues such as umbilical cord blood or wharton’s jelly among others.     

人和猴T淋巴细胞表面TRBC受体和E受体的比例研究

In 1985, rosette formation of human and macaque pan-T lymphocytes with tree shrew red blood cells (TRBC) (TRBC rosette) was first found by Ben K et al, showing different physico-chemical properties from that of rosette formation with sheep red blood cells (E-rosette). In order to approach the correlation between TRBC receptor, E receptor (CD2) and other differentiation antigens (CDs) on T lymphocytes, rosette inhibition assay and antigenic modulation or co-modulation were performed with monoclonal antibodies (McAbs) to CDs, and the distribution of TRBC receptor in other peripheral immunocytes, cell lines was also examined. TRBC rosette appeared in 88.8% of E rosette positive peripheral blood lymphocytes (E(+)-PBL) and in 4.16% of E(-)-PBL. TRBC receptor was also found on all T cell lines tested (CEM, H33 HJ-JA 1, Jurkat, MLA-144, Molt-3, Molt-4, Molt-4 clone 8, PEER) and some myeloid lines (U 937 and HL 60), but not on human granulocytes, B cell lines (Daudi, Raji and Reh) and myeloid line K 562. The modulation or co-modulation of CD 3, TCR, CD 5, CD 6 and CD 7 with McAbs OKT 3, T 108 (F 1), T 136 (F 101-15), T 149 (M-T 604) and T 152 (7 G 5) did not affect TRBC rosette formation of PBL. TRBC rosette of human and rhesus monkey PBL was not inhibited by T 11.1 McAb OKT 11 (CD 2 McAb), in contrast human and rhesus monkey E rosette formations were obviously blocked at inhibition rates of 77.9% and 49.3%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Variants of Defective Simian Papovavirus 40 (PARA) Characterized by Cytoplasmic Localization of Simian Papovavirus 40 Tumor Antigen

Three isolates of PARA (particle aiding replication of adenovirus)-adenovirus 7 out of a total of 112 clonal progeny derived by two successive plaque purifications in green monkey kidney cells (GMK) were found to induce the synthesis of simian papovavirus40 (SV 40) tumor (T) antigen in the cytoplasm of infected cells. The variant viruses induced plaque formation in human embryonic kidney cells which followed one-hit kinetics. In GMK cells, plaque formation followed two-hit kinetics which converted to first-order kinetics in the presence of additional helper adenovirus type 7. Analysis of plaque progeny from human cells showed that the progeny could replicate only in human cells, whereas progeny from monkey cells could multiply in both human and monkey cells. Heterologous human adenoviruses were able to enhance plaque formation by the variant viruses in monkey kidney cells. Neutralization tests indicated that both components of the populations had a type 7 adenovirus capsid. All three viruses were capable of inducing SV40 transplantation immunity in weanling hamsters. These results indicate the three variants are PARA-adenovirus 7 populations. Response of the induction of the synthesis of the cytoplasmic antigen to metabolic inhibitors was the same as for the synthesis of the nuclear SV40 T antigen. Different pools of sera which reacted with the intranuclear SV40 T antigen also detected the cytoplasmic antigen induced by the variant viruses. An adsorption experiment with cells containing either nuclear or cytoplasmic T antigen to remove tumor antibody from hamster sera also indicated that it is probably SV40 T antigen which is responsible for the cytoplasmic reaction. The species of the host cell-human, simian, or rabbit-appeared to play no role in the altered localization of this antigen. It is postulated that these PARA variants are further defective in some virus-mediated transport mechanism which shifts the T antigen from the cytoplasm to the nucleus.     

Identification of the Simian Virus 40 Which Replicates When Simian Virus 40-Transformed Human Cells Are Fused with Simian Virus 40-Transformed Mouse Cells or Superinfected with Simian Virus 40 Deoxyribonucleic Acid

Simian virus 40 (SV40) was rescued from heterokaryons of transformed mouse and transformed human cells. To determine whether the rescued SV40 was progeny of the SV40 genome resident in the transformed mouse cells, the transformed human cells, or both, rescue experiments were performed with mouse lines transformed by plaque morphology mutants of SV40. The transformed mouse lines that were used yielded fuzzy, small-clear, or large-clear plaques after fusion with CV-1 (African green monkey kidney) cells. The transformed human lines that were used did not release SV40 spontaneously or after fusion with CV-1 cells. From each mouse-human fusion mixture, only the SV40 resident in the transformed mouse cells was recovered. Fusion mixtures of CV-1 and transformed mouse cells yielded much more SV40 than those from transformed human and transformed mouse cells. The rate of SV40 formation was also greater from monkey-mouse than from human-mouse heterokaryons. Deoxyribonucleic acid (DNA) from SV40 strains which form fuzzy, largeclear, or small-clear plaques on CV-1 cells was also used to infect monkey (CV-1 and Vero), normal human, and transformed human cell lines. The rate of virion formation and the final SV40 yields were much higher from monkey than from normal or transformed human cells. Only virus with the plaque type of the infecting DNA was found in extracts from the infected cells. Two uncloned sublines of transformed human cells [W18 Va2(P363) and WI38 Va13A] released SV40 spontaneously. Virus yields were not appreciably enhanced by fusion with CV-1 cells. However, clonal lines of W18 Va2(P363) did not release SV40 spontaneously or after fusion with CV-1 cells. In contrast, several clonal lines of WI38 Va13A cells did continue to shed SV40 spontaneously.