Effects of the single or repeated inhalation exposure of Syrian hamsters to aerosols of 239PuO2

Male Syrian hamsters were scheduled to be exposed by inhalation approximately every 60 days for 1 year (7 exposures) to aerosols of 239PuO2 beginning at 84 days of age. Other hamsters were exposed once when 84 or 320 days of age. Plutonium-239 deposited in the lungs by the repeated inhalation exposures was cleared from the lungs at a rate similar to that following a single inhalation exposure. The incidence of radiation pneumonitis, bronchiolar epithelial hyperplasia, and alveolar squamous metaplasia were the only lesions that were related to radiation dose. Only two primary lung tumours were found among the hamsters exposed to 239PuO2. No primary lung tumours were found in the control hamsters. It was concluded that the incidence of lung tumours was not increased by the protraction of the alpha radiation dose to the lungs from repeated inhalation exposure.     

Transforming activity and the oncogenicity of simian adenovirus SA7 DNA]

The transforming and oncogenous activity of uncleaved DNA of simian adenovirus SA7 (AdSA7) and the products of its restriction by endonucleases R. Bam HI and R. SalI was studied. It was shown that uncleaved virus DNA transformed the rat kidney cells and rat embryo fibroblasts and induced tumors in newborn hamsters. AdSA7 DNA, hydrolysed by R. Bam HI, posessed the transforming activity. The mixture of DNA fragments, obtained after hydrolysis by R. SalI was oncogenous in hamsters.     

Adenovirus Transformation of Hamster Embryo Cells

Inoculation of hamster embryo cell cultures with human adenovirus type 12 (Ad12) or simian adenovirus (SA7) resulted in the formation of foci of morphologically transformed cells within 12 days. The rapid appearance of well-defined foci was dependent upon the transfer of cells into new plates, with sufficient dilution after virus adsorption, and was independent of virus dose. Dose-response studies showed linearity of focus formation with dilution of Ad12 or SA7. Results averaged from several experiments show plaque-forming unit to focus-forming unit ratios of approximately 1.8 x 10(6) for Ad12 and 2.6 x 10(5) for SA7. Other experiments showed that most of the adenovirus involved in transformation was adsorbed by 3 hr. Cell lines derived from SA7 transformed cells produced tumors within 19 days when inoculated intradermally into young adult hamsters. Such cell-induced tumors histologically resembled SA7 virus-induced hamster tumors. Formation of tumors with SA7 transformed cells was inhibited by prior immunization of test animals with SA7 or Ad12 virus.     

Hyaluronidase in sera of tumour-bearing nude mice

Cancer cell lines often secrete hyaluronidase, suggesting that this enzyme could be used as a marker of growing tumours. We have measured hyaluronidase in the sera of non-grafted mice and mice grafted with human tumour-derived hyaluronidase-secreting H460M and SA87 cells or non-secreting CB 193 cells. Mouse serum hyaluronidase was measured at pH 3.8 using the enzyme-linked sorbent assay (ELSA) technique by reference to human serum whose activity at pH 3.8 was determined by the Reissig technique. The serum hyaluronidase in non-grafted mice ranged from 310-520 mU l^?1 (mean±SD 432±70 mU l^?1, median 440 mU l^?1). Hyaluronidase increased in the sera of tumour-bearing mice grafted with H460M cells or with SA87 cells, but not in the sera of mice grafted with CB 193 cells. Serum hyaluronidase activity in H460M or SA87 tumour-bearing mice correlated with the tumour mass, increased with time, and decreased after tumour removal. Zymography detected two different hyaluronidase forms in the sera of non-grafted mice: type 1 had only one hyaluronidase band and type 2 had five different bands. In both types, enzyme augmentation in tumour-bearing mice correlated with the presence of an additional enzyme band that was not seen in normal sera and that migrated as the cancer cell enzyme did; there was no augmentation of the normal isoform(s). These results show that serum hyaluronidase can be used to follow the development of tumours in mice grafted with hyaluronidase-secreting cells.     

Immunogenic properties of hamster tumours of herpesvirus hominis aetiology

Summary Cells derived from HSV-induced tumour lines were attenuated by X-irradiation (15,000 rads) and used to immunize groups of hamsters prior to challenge with homologous tumour cells. The results indicate that the three HSV tumours studied possess a weak transplantation antigen(s). Some cross-immunity between these tumours was observed, although the rejection antigen(s) were distinct from those of a SV40-induced hamster tumour line.Bacillus Calmétte-Guérin (BCG) inoculated in admixture with X-irradiated tumour cells or given 7 days prior to immunization with X-irradiated tumour cells increased host immunocompetence to subsequent tumour cell challenge. Thus, immunization with BCG was shown to induce a higher level of immunity than immunization with attenuated tumour cells alone, as demonstrated on re-challenge of hamsters with homologous tumour cells.     

Hybrids of Human and Monkey Adenoviruses (Adeno-Adeno Hybrids) That Can Reproduce in Monkey Cells: Biological and Molecular Genetic Peculiarities

A highly oncogenic monkey adenovirus SA7(C8) facilitates the reproduction of human adenovirus type 2 (Ad2) in monkey cells. Upon mixed infection of monkey cells with both viruses, these viruses recombine producing defective adeno-adeno hybrids Ad2C8 serologically identical to Ad2 and capable of assisting Ad2 to reproduce in monkey cells. Ad2C8 and Ad2 form an intercomplementary pair inseparable in monkey cells. Unlike oncogenic SA7(C8), Ad2C8 is a nononcogenic virus for hamsters but is able to induce tumor antigens of this virus (T and TSTA). Molecular genetic analysis of 68 clones of adeno-adeno hybrids revealed that the left part of their genome consists of Ad2 DNA, and the right part contains no less than 40% of the viral SA7(C8) genome where E2A, E3, and E4 genes are located. Apparently, the products of these genes contribute to the composition of adenoviral tumor antigens, while the E4 gene is involved in complementation of monkey and human adenoviruses and makes a contribution to host range determination of these viruses.     

Effect of BCG on Friend Disease Virus in Mice

NONSPECIFIC stimulation of the reticulo-endothelial system and resistance against tumorigenesis are produced by injection of attenuated Mycobacterium bovis (BCG). Biozzi et al.¹ demonstrated resistance to Ehrlich's ascites tumour in BCG-immune mice and Halpern et al.² showed that such immunization effected control of T-8 tumours in rats. Further, at least partial control of other tumours^3–6 has been effected by this procedure in mice and hamsters.     

Effect of Gonadectomy on the Androgen-Dependent Behavior of Ganglion Cell-Like Cells in Djungarian Hamsters (Phodopus sungorus)

Ganglion cell-like (GL) cells reside in the dermis of the ventral skin of mature male Djungarian hamsters (Phodopus sugorus) and express androgen receptor (AR). To assess whether GL cells have androgen-dependent behavior, we evaluated the histologic changes of GL cells after gonadectomy. Five male and 5 female hamsters were gonadectomized at the age of 4 wk and necropsied 14 wk later. The number, distribution, and proliferative activity of GL cells in the thoracoabdominal and dorsal skins were evaluated histologically and compared with those of corresponding intact animals. GL cells were more numerous, were distributed throughout the skin more widely, and had higher proliferative activity in the intact male hamsters than in their gonadectomized counterparts. Similar trends regarding these 3 parameters were seen in ovariectomized compared with intact female hamsters and between intact male and intact female hamsters. These results suggest that the GL cells of Djungarian hamsters demonstrate sex-associated differences in their distribution and proliferative activity and that androgen may be involved in the development of these cells.Abbreviations: AR, androgen receptor; GL cell, ganglion cell-like cellGanglion cell-like (GL) cells reside in the dermis of the abdominal and thoracic skin of mature male Djungarian hamsters (Phodopus sungorus).^1,7 GL cells have a small round nucleus with an apparent nucleolus and abundant basophilic foamy cytoplasm. These cells usually aggregate to form nests accompanied by various volumes of stromal collagen fibers. The nests increase in size and number with maturation. The nuclei of GL cells have a positive reaction for androgen receptor (AR), and the cytoplasm is positive for vimentin.^1,7 Although the morphologic characteristics and various immunophenotypes of GL cells have been documented, their behavior and role remain almost unclear. Some authors speculate that increased levels of testosterone may influence GL cell proliferation and the oncogenesis of atypical skin fibromas preferentially arising in this species.¹The current study aims to elucidate the androgen-dependent behavior of GL cells and compare the histologic changes of GL cells in gonadectomized Djungarian hamsters with those in intact control animals.     

Hamsters as a Model of Severe Acute Respiratory Syndrome Coronavirus-2

Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), the cause of coronavirus disease 2019 (COVID-19), rapidly spread across the world in late 2019, leading to a pandemic. While SARS-CoV-2 infections predominately affect the respiratory system, severe infections can lead to renal and cardiac injury and even death. Due to its highly transmissible nature and severe health implications, animal models of SARS-CoV-2 are critical to developing novel therapeutics and preventatives. Syrian hamsters (Mesocricetus auratus) are an ideal animal model of SARS-CoV-2 infections because they recapitulate many aspects of human infections. After inoculation with SARS-CoV-2, hamsters become moribund, lose weight, and show varying degrees of respiratory disease, lethargy, and ruffled fur. Histopathologically, their pulmonary lesions are consistent with human infections including interstitial to broncho-interstitial pneumonia, alveolar hemorrhage and edema, and granulocyte infiltration. Similar to humans, the duration of clinical signs and pulmonary pathology are short lived with rapid recovery by 14 d after infection. Immunocompromised hamsters develop more severe infections and mortality. Preclinical studies in hamsters have shown efficacy of therapeutics, including convalescent serum treatment, and preventatives, including vaccination, in limiting or preventing clinical disease. Although hamster studies have contributed greatly to our understanding of the pathogenesis and progression of disease after SARS-CoV-2 infection, additional studies are required to better characterize the effects of age, sex, and virus variants on clinical outcomes in hamsters. This review aims to describe key findings from studies of hamsters infected with SARS-CoV-2 and to highlight areas that need further investigation.

Coronavirus disease 2019 (COVID-19) is caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), a novel betacoronavirus that was first detected in Wuhan, China at the end of 2019.³¹ Coronavirus infections predominantly present with either respiratory or gastrointestinal manifestations, depending on the strain and host. While many coronavirus infections result in mild clinical symptoms, SARS-CoV-2 is highly pathogenic and poses significant health concerns.^31,58,78 Although initial clinical signs are attributed to the respiratory system, severe infections result in systemic complications, such as acute cardiac and renal injury, secondary infections, and shock.^31,58SARS-CoV-2 relies on a structural surface spike glycoprotein to establish infection. The spike protein binds to the angiotensin-converting enzyme 2 (ACE2) receptor on host cells to gain entry in a receptor-mediated fashion. This interaction facilitates both human-to-human transmission and cross-species infection.⁷⁷ Species tropism is determined by the presence of ACE2 residues that recognize the SARS-CoV-2 spike protein. Animals permissive for SARS-CoV-2 infection include cats, ferrets, pigs, nonhuman primates, select genetically modified mice, and hamsters.^5,7,23,37,67 Susceptible species can be both intermediate hosts and sources of infection of SARS-CoV-2 for humans.⁷⁷ Rodents, such as mice and hamsters, are ideal models for the study of COVID-19 due to their small size, ready availability, low cost of care, SPF status, and in-depth characterization across a variety of translational models, including past and present betacoronavirus infections.^60,61 Although transgenic mice expressing human ACE2 are susceptible to SARS-CoV-2 infection, Syrian hamsters (Mesocricetus auratus) naturally express ACE2 residues that recognize the SARS-CoV-2 spike protein.^5,46,84 As such, Syrian hamsters are a valuable animal model for studying COVID-19.Syrian hamsters, commonly referred to as golden hamsters, belong to the family Cricetidae and have a natural geographic range of arid southeast Europe and Asia Minor. Additional members of the Cricetidae family used in biomedical research include Chinese hamsters (Cricetulus griseus), European hamsters (Cricetus cricetus), Armenian hamsters (Cricetulus migratorius), and dwarf hamsters (Phodopus species). Unless otherwise noted, any mention of hamsters in this overview refers to Syrian hamsters. Laboratory hamsters primarily originated from one Syrian litter captured in 1930. Progeny of this litter were first imported into the United States in 1938.⁵⁰ Outbred Syrian hamsters are widely available; recently developed transgenic hamsters are increasingly used in biomedical research and may provide unique insight into SARS-CoV-2 infections.^22,44 Syrian hamsters have a rich history in biomedical research and can be used to model cancer and infectious, metabolic, cardiovascular, and respiratory diseases.⁵⁰Hamsters play an important role in SARS-CoV-2 studies. This is due, in part, to their susceptibility to the first described highly pathogenic coronavirus infection in the 21st century, severe acute respiratory syndrome (SARS-CoV). SARS-CoV emerged in late 2002 in Southern China. Although individuals in more than 20 countries contracted SARS-CoV, the spread was quickly contained, with the last reported case in July 2003.^16,40 After experimental infection with SARS-CoV, hamsters developed high viral loads in the lungs and nasal turbinates.^{15,32,56,62,69} Pulmonary pathology included inflammation, cell necrosis, and consolidation without clinical signs of disease.⁶¹ Based on their susceptibility to SARS-CoV and natural expression of ACE2 capable of recognizing the SARS-CoV-2 spike protein, hamsters have been a preferred model of SARS-CoV-2. Hamster studies have replicated key aspects of SARS-CoV-2 infections in humans, including viral replication, transmission, and pathology. Furthermore, hamsters are a model organism for developing and testing novel preventions and therapeutics. However, using hamsters in biomedical research has several key limitations, including the lack of reagents, especially antibodies, suitable for use with hamster tissue and the relatively few established transgenic hamsters compared to mice. The purpose of this review is to describe key findings of hamster models of SARS-CoV-2 and to highlight gaps in our current understanding that will require further investigation.     

Hybrid of Monkey and Human Adenoviruses

Following joint replication of monkey SA7 adenovirus (C8 strain) and human adenovirus type 2 in green monkey kidney tissue culture, a virus possessing the properties of a hybrid was obtained. It was designated Ad2C8. Ad2C8 preparations contained two types of viral particles: human adenovirus type 2, and hybrid particles. The hybrid virions multiplied in green monkey kidney cells in the presence of human adenovirus types 1, 2, and 3, but not 3 and 7, and acquired the capsid of the helper adenovirus. The hybrid can serve as a helper for human adenoviruses. It can apparently induce T antigen of the C8 virus but, in contrast to the latter, does not induce tumors in hamsters.     

Changes in the antitumor resistance of hamsters after experimental removal of non-fixed macrophages

It has been demonstrated that tumours do not appear after subcutaneous transplantation of small amounts (10(2), 2 X 10(2] of AD-12 sarcoma cells to intact hamsters, whereas tumours do appear in 53-72% of hamsters inoculated with starch suspension prior to transplantation of the same amounts of tumour cells (tumour growth stimulation phenomenon). The results show that tumour growth stimulation in hamsters pre-inoculated with starch suspension is connected with distraction of macrophages from the region of tumour cell localization to the abdominal area.     

Influence of Genetic Factors on the Induction of Mammary and Intestinal Adenocarcinomas in Inbred Syrian Golden Hamsters

INBRED lines of Syrian golden hamsters, Mesocricetus auratus auratus, respond to subcutaneous injection of polycyclic hydrocarbons^1,2 and to oncogenic viruses³ with varying rapidity and tumour incidence, which depend on genetic factors. We have investigated the inherited susceptibility or resistance of Syrian hamsters to the development of intestinal and/or mammary adenocarcinoma after the administration, by stomach tube, of 250 mg of 20-methylcholanthrene (MC) in corn oil three times a week (5 mg in 0.5 ml.) for 17 weeks. Thirty males and thirty females aged 90 days of nine inbred strains were used and, after the course of MC gavage, they were left until they looked ill and were then killed. Autopsies were done between 4 and 39 weeks after the last MC feeding or at age 34–69 weeks in seven BIO lines (Telaco, Bar Harbor, Maine) (Table 1). At least eleven males or eighteen females survived for at least 4 weeks after the last feeding. The incidence of their tumours is shown in Table 2.     

Hybrids of human and monkey adenoviruses (adeno-adeno hybrids) that can reproduce in monkey cells: biological and molecular genetic peculiarities

A highly oncogenic monkey adenovirus SA7(C8) facilitates the reproduction of human adenovirus type 2 (Ad2) in monkey cells. Upon mixed infection of monkey cells with both viruses, these viruses recombine producing defective adeno-adeno hybrids Ad2C8 serologically identical to Ad2 and capable of assisting Ad2 to reproduce in monkey cells. Ad2C8 and Ad2 form an intercomplementary pair inseparable in monkey cells. Unlike oncogenic SA7(C8), Ad2C8 is a nononcogenic virus for hamsters but is able to induce tumor antigens of this virus (T and TSTA). Molecular genetic analysis of 68 clones of adeno-adeno hybrids revealed that the left part of their genome consists of Ad2 DNA, and the right part contains no less than 40% of the viral SA7(C8) genome where E2A, E3, and E4 genes are located. Apparently, the products of these genes contribute to the composition of adenoviral tumor antigens, while the E4 gene is involved in complementation of monkey and human adenoviruses and makes a contribution to host range determination of these viruses.     

Salicylic acid antagonism of EDS1‐driven cell death is important for immune and oxidative stress responses in Arabidopsis

Reactive oxygen species (ROS) have emerged as signals in the responses of plants to stress. Arabidopsis Enhanced Disease Susceptibility1 (EDS1) regulates defense and cell death against biotrophic pathogens and controls cell death propagation in response to chloroplast‐derived ROS. Arabidopsis Nudix hydrolase7 (nudt7) mutants are sensitized to photo‐oxidative stress and display EDS1‐dependent enhanced resistance, salicylic acid (SA) accumulation and initiation of cell death. Here we explored the relationship between EDS1, EDS1‐regulated SA and ROS by examining gene expression profiles, photo‐oxidative stress and resistance phenotypes of nudt7 mutants in combination with eds1 and the SA‐biosynthetic mutant, sid2. We establish that EDS1 controls steps downstream of chloroplast‐derived O₂^?? that lead to SA‐assisted H₂O₂ accumulation as part of a mechanism limiting cell death. A combination of EDS1‐regulated SA‐antagonized and SA‐promoted processes is necessary for resistance to host‐adapted pathogens and for a balanced response to photo‐oxidative stress. In contrast to SA, the apoplastic ROS‐producing enzyme NADPH oxidase RbohD promotes initiation of cell death during photo‐oxidative stress. Thus, chloroplastic O₂^?? signals are processed by EDS1 to produce counter‐balancing activities of SA and RbohD in the control of cell death. Our data strengthen the idea that EDS1 responds to the status of O₂^?? or O₂^??‐generated molecules to coordinate cell death and defense outputs. This activity may enable the plant to respond flexibly to different biotic and abiotic stresses in the environment.     

Metabolism of methylmercury in rabbits and hamsters

The metabolism of²⁰³Hg-labeled methylmercury chloride (MeHg) has been studied in rabbits and hamsters. Rabbits were administered 1.6 μmol MeHgCl/kg bw intravenously, and hamsters 40 μmol/kg bw orally. Urine and feces were collected daily and groups of four animals killed after 1 h, 1 d, or 7 d. The concentration of²⁰³Hg in blood, liver, kidney, spleen, lung, heart, and brain was determined by gamma counting. In both animal species, the clearance of²⁰³Hg in the brain was slower than in other tissues. In the rabbits the brain²⁰³Hg concentration increased during the whole experimental period. Rabbits excreted²⁰³Hg primarily in feces (about 20% of the dose within 1 wk), and much less in urine (<2%). In contrast, hamsters very efficiently excreted²⁰³Hg in urine (50% in 1 wk). The fecal excretion was similar to that of the rabbits. Separation of inorganic Hg and MeHg in urine from hamsters by ion exchange chromatography showed that about 90% of the urinary²⁰³Hg was excreted as MeHg.     

Using small molecule reagents to selectively modify epitopes based on their conformation

PrP^Sc is an infectious protein. The only experimentally verified difference between PrP^Sc and its normal cellular isoform (PrP^C) is conformational. This work describes an approach to determining the presence of surface exposed or sequestered amino acids present in the PrP^Sc isoform. The N-hydroxysuccinimide esters of acetic acid and 4-trimethylammoniumbutyric acid were synthesized and reacted with detergent-solubilized brain extracts from Me7-infected mice, uninfected mice, 263K-infected hamsters or uninfected hamsters. These reaction mixtures were analyzed by western blots probed with the antibodies 3F4, 6D11, 7D9, AG4, AH6, GE8 or MAB5424. The 3F4, 6D11, AH6, and GE8 antibodies recognize an epitope that is encrypted in the PrP^Sc isoform, but exposed in the PrP^C isoform. These reagents permit the detection of prion infected brain extracts without the need for proteinase K digestion. In addition they can be used, with an appropriate antibody, to determine which amino acids of PrP^Sc are exposed on the surface and which are encrypted, thus providing useful structural information. This approach was used to distinguish between the 263K and drowsy strains of hamster-adapted scrapie without the use of proteinase K.     

Using small molecule reagents to selectively modify epitopes based on their conformation

PrP^Sc is an infectious protein. The only experimentally verified difference between PrP^Sc and its normal cellular isoform (PrP^C) is conformational. This work describes an approach to determining the presence of surface exposed or sequestered amino acids present in the PrP^Sc isoform. The N-hydroxysuccinimide esters of acetic acid and 4-trimethylammoniumbutyric acid were synthesized and reacted with detergent-solubilized brain extracts from Me7-infected mice, uninfected mice, 263K-infected hamsters or uninfected hamsters. These reaction mixtures were analyzed by western blots probed with the antibodies 3F4, 6D11, 7D9, AG4, AH6, GE8 or MAB5424. The 3F4, 6D11, AH6, and GE8 antibodies recognize an epitope that is encrypted in the PrP^Sc isoform, but exposed in the PrP^C isoform. These reagents permit the detection of prion infected brain extracts without the need for proteinase K digestion. In addition they can be used, with an appropriate antibody, to determine which amino acids of PrP^Sc are exposed on the surface and which are encrypted, thus providing useful structural information. This approach was used to distinguish between the 263K and drowsy strains of hamster-adapted scrapie without the use of proteinase K.     

The Laser Treatment of Experimental Malignant Tumours

Some of the results of experiments performed during the past two years to assess effects of laser energy on experimental malignant tumours are reviewed. Twenty types of malignant tumours (most in the cheek pouch and 11 of human origin) were treated in over 700 Syrian hamsters. Results of laser treatment of malignant melanomas and thyroidal carcinomas are presented. A human patient with malignant melanoma treated by laser energy is described. Investigation of thermal effect revealed that the laser-treated tumour remained warm for about one minute, while the cautery-treated tumour cooled to normal temperature in five seconds. Direct action of laser on superficial tumours is possible; deeper lesions must be exposed surgically. Laser energy has a selective effect on certain malignant tumours, resulting in their progressive regression and ultimate dissolution. All hamsters with implanted malignant melanomas and carcinomas of human origin, after completion of a course of laser treatment, showed no gross or histologic evidence of tumour up to the date of last observation.     

Retention of Antigen Specificity of Murine Sarcoma Viruses grown in Hamster Cells <Emphasis Type="Italic">in vitro</Emphasis>

TUMOURS can be induced in hamsters by the various strains of murine sarcoma virus (MSV)^1–6. Tumours differ, however, in the antigens which are expressed. Whereas the cell line HT-1, derived from early passages of a hamster tumour induced by the Moloney strain of MSV (M-MSV), contains no trace of infectious virus or virion antigen^2,7, tumours induced by the Harvey (H), Kirsten (Ki) and later passages of the M-MSV-(GLV) viruses have yielded sarcoma viruses with a hamster-specific host range^3–6,8 which do not share envelope^4–6,9 or group specific¹⁰ antigens with murine viruses. The HT-1 cell does retain the MSV genome which can be rescued by murine leukaemia viruses². Such rescued viruses are termed pseudo-types and contain the envelope and group-specific antigens of the rescuing virus. The virus preparation from tumours induced by M-MSV(GLV) differed from the other hamster-specific viruses in that a non-sarcomagenic C-type virus could be isolated from cultures infected beyond the cell transformation end point⁶. This virus was also hamster-specific in host range and antigenic properties and specifically interfered with cell transformation by the various hamster-specific virus strains⁹. This virus also shared an ether-stable virion-antigen with a C-type virus found in a lymphoma which occurred spontaneously in a hamster¹⁰. This shared antigen seems to be the principal structural polypeptide of hamster C-type viruses and is structurally similar but antigenically distinct from its mouse homologue (unpublished work of S. O., C. Foreman, G. K. and R. V. G.). These findings led us to propose that the hamster-specific non-sarcomagenic C-type virus was a hamster leukaemia virus (in the generic but not necessarily the pathological sense) and the virus is therefore designated HaLV^9,10. The hamster-specific sarcoma viruses are considered to be pseudotypes of MSV rescued in vivo by HaLV and are abbreviated accordingly; for example, M-MSV(HaLV) represents the hamster-specific sarcoma virus rescued from M-MSV induced tumours. This is plausible because HaLV is able to rescue the MSV genome from HT-1 cells⁶. (This change in the nomenclature has been made in order to reflect the antigenic composition of the hamster-specific virus more accurately. In addition, to indicate the virus rescued from M-MSV(GLV)-induced hamster tumours, a terminal G is added after the parentheses. This has been done only to distinguish it from the virus obtained from M-MSV induced hamster tumours, for there is no evidence of residual activity from GLV.)