Evidence for the progressive nature of neoplastic transformation in vitro.
about
Identification and assessment of tumor-oromoting and cocarcinogenic agents: state-of-the-art in vitro methodsCrocidolite induces cell transformation and p53 gene mutation in BALB/c-3T3 cellsIdentification of a single chromosome in the normal human genome essential for suppression of hamster cell transformationIncipient and overt stages of neoplastic transformationNeoplastic transformation of normal and carcinogen-induced preneoplastic Syrian hamster embryo cells by the v-src oncogene.In vitro cell transformation assays for an integrated, alternative assessment of carcinogenicity: a data-based analysis.Studies of the T1 and T2 of intracellular water as a function of frequency in normal and transformed fetal cells.Immunological approach to hepatocellular carcinoma.Identification of genes associated with tumor suppression in Syrian hamster embryo cells.Expression of Gab1 lacking the pleckstrin homology domain is associated with neoplastic progression.Regulation of normal differentiation in mouse and human myeloid leukemic cells by phorbol esters and the mechanism of tumor promotionAlternative strategies for carcinogenicity assessment: an efficient and simplified approach based on in vitro mutagenicity and cell transformation assays.Nontumoral, benign ad malignant stages of transformation of a diploid pig cell line. A review.Role of a tumor-suppressor gene in the negative control of anchorage-independent growth of Syrian hamster cells.Increased radiation-induced transformation in C3H/10T1/2 cells after transfer of an exogenous c-myc gene.In vitro models of carcinogenesis: expression of recessive genes by chromosomal mutations.Cellular differentiation and neoplasia: characterization of subpopulations of cells that have neoplasia-related growth properties in Syrian hamster embryo cell cultures.Experimental control of neoplastic progression in cell populations: Foulds' rules revisited.Induction of kidney tumours by a single dose of dimethylnitrosamine: dose response and influence of diet and benzo(a)pyrene pretreatment.Limitations of the clonal agar assay for the assessment of primary human ovarian tumour biopsies.Radiation and chemically induced transformation: free radicals, antioxidants and cancer.Expression of the alpha subunit of human chorionic gonadotropin is specifically correlated with tumorigenic expression in human cell hybrids.Malignant transformation induced by incorporated radionuclides in BALB/3T3 mouse embryo fibroblasts.Correlation of patterns of anchorage-independent growth with in vivo behavior of cells from a murine fibrosarcoma.Induction of gene mutation in and cell transformation of mammalian cells by modified purines: 2-aminopurine and 6-N-hydroxylaminopurine.Increasing metastatic potential is associated with increasing genetic instability of clones isolated from murine neoplasms.Constitutive uncoupling of pathways of gene expression that control growth and differentiation in myeloid leukemia: a model for the origin and progression of malignancyProbabilistic view of the transformation of cultured C3H/10T1/2 mouse embryo fibroblasts by 3-methylcholanthrene.Adaptive evolution of degrees and kinds of neoplastic transformation in cell cultureFocus formation and neoplastic transformation by herpes simplex virus type 2 inactivated intracellularly by 5-bromo-2'-deoxyuridine and near UV light.Neoplastic conversion of preneoplastic Syrian hamster cells: rate estimation by fluctuation analysis.Chemical carcinogens transform BHK cells by inducing a recessive mutation.Chemical carcinogens produce mutations to ouabain resistance in transformable C3H/10T1/2 Cl 8 mouse fibroblastsA carboxy-terminal truncated insulin receptor substrate-1 dominant negative protein reverses the human hepatocellular carcinoma malignant phenotype.Loss of tumor-suppressive function during chemically induced neoplastic progression of Syrian hamster embryo cells.A contact-insensitive subpopulation in Syrian hamster cell cultures with a greater susceptibility to chemically induced neoplastic transformation.Alternatives to the carcinogenicity bioassay: in silico methods, and the in vitro and in vivo mutagenicity assays.Alternatives to the carcinogenicity bioassay for toxicity prediction: are we there yet?Relationship between increasing concentrations of two carcinogens and statistical image descriptors of foci morphology in the cell transformation assay.In Vitro-In Vivo Carcinogenicity.
P2860
Q23914589-7D32D9AA-0A8D-4910-87FE-7A7FBEB414FEQ24169605-51B8EB3C-A9EE-4C14-B99F-40855E29F84FQ24568213-90385939-26F1-4292-9ADC-8C8C443D61CAQ28385847-BE40F070-7F6A-47D3-B5F0-9441BF520BD2Q30449980-F9759AB1-502F-42D8-8F7B-8A8BC1A3DE83Q30576475-42D4A9DC-47D7-4F79-BAF8-14C3311450C8Q31096599-C9C79A21-2919-404E-9201-C9D8A2350713Q32147095-DE909973-856A-4215-95BA-7F625051AF6BQ33295655-FAFEE9CD-D416-4AAF-8F15-606EA11C76EAQ34012464-228E896F-00A8-4FAC-B0B4-82C766B8A452Q34037444-F8D7F745-EE4B-4F23-8236-8320E85D5BECQ34170350-C15EA483-EFBF-4C69-BA83-D44F66D6F183Q34239530-CFA43722-32FE-499F-8223-D6AEAD5DF1F6Q34318909-3281D446-E83E-4F6D-A9CA-F803BB1EC427Q34631459-E18DDF69-3A79-41BF-BCA6-7072E08F3231Q35032665-CB5F4565-0264-4E10-AF49-3DCFF406FFEDQ35463089-4FAA6745-42B5-4904-95FA-D913985F4AB1Q35586746-84FAA63F-625F-479F-8F48-A82FED393F80Q36043692-149A7FB3-1AE0-4FAF-BF38-D776215977FAQ36046590-3D4B0835-8E2F-4DD0-8ECB-5B66AEEC07D0Q36290846-2529D197-5A70-4C31-A370-54F92E4207FCQ36316210-CAB74975-C2FE-4ADB-88C7-ACC565753C25Q36326839-16350592-4F92-4771-9FB4-A8E982BDDE4FQ36356797-6AAF525D-A375-4F8E-B710-7A18F8F1A00EQ36368940-82C91571-F154-4325-937B-A2CF8FA5FE5CQ36379155-F8EC182F-6636-4638-A798-D4D22A3560C9Q36412087-38722357-8150-4FF8-B43B-298C33B35D44Q36419025-A53EBB54-B047-41E1-9468-9D81D359D70FQ36812946-CC7E26A2-2D54-4250-B168-091571FE4A26Q36933749-674C160B-374A-458C-9E18-11D3BD8BF5FBQ36939142-13744A72-23BF-41EB-8CB9-58FE52CEB699Q36970871-DDF24E2D-E4AC-416F-A8EB-E25D4BAF9334Q37316624-C010B2D5-A8C5-41BA-8A0A-E4CA32E65DB0Q37361198-6C4E873F-2D92-403A-8CD7-D4A272FD2B42Q37394889-517A423F-B85B-4941-AE95-DCC557F578C3Q37525160-25739383-24C6-4A5C-BD78-22FB429B92B1Q37741223-6C9BCB99-0F46-414E-8CB9-811FDA88F4B0Q37987563-8818F922-FE69-454A-887C-D376BD839C64Q38727621-F79ACEB9-3557-4D38-8F87-B88AD1877AFDQ38752832-A2E2F59D-E176-458D-9EBF-633EB6758C08
P2860
Evidence for the progressive nature of neoplastic transformation in vitro.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on August 1978
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Evidence for the progressive nature of neoplastic transformation in vitro.
@en
Evidence for the progressive nature of neoplastic transformation in vitro.
@nl
type
label
Evidence for the progressive nature of neoplastic transformation in vitro.
@en
Evidence for the progressive nature of neoplastic transformation in vitro.
@nl
prefLabel
Evidence for the progressive nature of neoplastic transformation in vitro.
@en
Evidence for the progressive nature of neoplastic transformation in vitro.
@nl
P2860
P356
P1476
Evidence for the progressive nature of neoplastic transformation in vitro.
@en
P2093
P2860
P304
P356
10.1073/PNAS.75.8.3761
P407
P577
1978-08-01T00:00:00Z