Prostate cancer and other xenografts from cells in peripheral blood of patients.

Good models for the investigation of human prostate cancer are few. Cells from approximately 9.2-21 ml of peripheral blood from patients with metastatic prostate cancer or metastatic colon cancer were injected s.c. into nude mice. Prostate cancer from 2 of 11 patients and colon cancer from 1 of 3 patients were found to be growing as metastases in the lungs of the nude mice. To our knowledge, this is the first report of the formation of xenografts from carcinoma cells taken directly from the peripheral blood of patients. Expanding circulating cancer cells with this approach may have important translational applications including: (a) development of models of human cancers; and (b) sampling of cancers from specific patients for novel molecular and therapeutic approaches.

A new human prostate carcinoma cell line, 22Rv1.

A cell line has been derived from a human prostatic carcinoma xenograft, CWR22R. This represents one of very few available cell lines representative of this disease. The cell line is derived from a xenograft that was serially propagated in mice after castration-induced regression and relapse of the parental, androgen-dependent CWR22 xenograft. Flow cytometric and cytogenetic analysis showed that this cell line represents one hyper DNA-diploid stem line with two clonal, evolved cytogenetic sublines. The basic karyotype is close to that of the grandparent xenograft, CWR22, and is relatively simple with 50 chromosomes. In nude mice, the line forms tumors with morphology similar to that of the xenografts, and like the parental CWR22 and CWR22R xenografts, this cell line expresses prostate specific antigen. Growth is weakly stimulated by dihydroxytestosterone and lysates are immunoreactive with androgen receptor antibody by Western blot analysis. Growth is stimulated by epidermal growth factor but is not inhibited by transforming growth factor-beta1.

Molecular cytogenetic studies of a serially transplanted primary prostatic carcinoma xenograft (CWR22) and four relapsed tumors.

BACKGROUND: Established cell lines or xenografts from prostatic carcinoma have been infrequently studied cytogenetically. CWR22 and CWR22-R are xenografts that are unique in offering one strongly androgen-dependent and several relapsed strains of a human prostate cancer that can be investigated in the laboratory. We report on the cytogenetic characterization of the hormone-dependent CWR22, and the relapsed CWR22-R serially transplanted xenografts, in our laboratory. METHODS: We utilized a suspension harvest of the xenograft tissue to optimize our yield for metaphase chromosome studies and analyzed the hormone-dependent CWR22 and four relapsed CWR22-R xenografts. These studies were accomplished using standard G-banded analysis and fluorescence in situ hybridization (FISH). A variety of DNA probes including alpha-satellite DNA probes, and chromosomal libraries, were utilized for the FISH analysis. RESULTS: Utilizing both standard cytogenetic analysis and FISH studies we have more precisely defined the CWR22 xenograft: 49,XY,+i(1)(q10),-2, der(4)t(2;4)(p21;q33), +7,+8,+12[7]/50,XY,idem, +der(2)t(2;4)(p21;q33)del(2)(q13q33)[13]. Four relapsed xenografts, CWR22R-2152, CWR22R-2524, CWR22R-2274, and CWR22R-2272 were also studied. Each of these lines demonstrated a different karyotype. CONCLUSIONS: The CWR22 karyotype offers the simplest reported karyotype for a prostate cancer tissue culture cell line or xenograft; this makes CWR22 an attractive candidate for studies of genetic changes associated with the relapse of prostate cancer treated with androgen withdrawal. Four separate, serially transplanted, relapsed CWR22-R xenografts were detected, each with a separate karyotype.

CWR22: the first human prostate cancer xenograft with strongly androgen-dependent and relapsed strains both in vivo and in soft agar.

Most patients' prostate cancers respond to androgen deprivation but relapse after periods of several months to years. Only two prostate cancer xenografts, LNCaP and PC-346, have been reported to be responsive to androgen deprivation and to relapse subsequently. Both of these tumors shrink slightly, if at all, and relapse less than 5 weeks after androgen withdrawal. After androgen withdrawal, the human primary prostate cancer xenograft CWR22 regresses markedly, and prostate-specific antigen (PSA) falls up to 3000-fold in the blood of mice. PSA usually returns to normal. In some animals, the tumor relapses and is then designated CWR22R. In these animals, PSA starts to rise approximately 2-7 months, and tumor begins to grow 3-10 months after castration. Animals with CWR22 need to be euthanized because of large tumors 6-12 weeks after the transplantation of CWR22. Androgen withdrawal prolongs life approximately 3-4-fold.

CWR22: androgen-dependent xenograft model derived from a primary human prostatic carcinoma.

The long-term propagation of primary human prostate cancer (PCA) in vivo or in vitro has been rare. Most such PCAs are phenotypically different from most PCAs in humans; i.e., they make little prostate specific antigen and respond little, if at all, to androgen deprivation. A serially transplantable, primary human PCA, designated CWR22, exhibits a clonal cytogenetic aberration, causes high elevations of prostate specific antigen in the peripheral blood of nude mice, and is unusually responsive to androgen deprivation as compared with other xenografts. Studies of mRNA from CWR22 have demonstrated the expression of prostate specific antigen and the epidermal growth factor receptor family including erbB1/epidermal growth factor receptor, erbB2/neu, and erbB3, but not erbB4. A ligand for these receptors, the neu differentiation factor, is also expressed.

Xenografts of primary human prostatic carcinoma.

BACKGROUND: Prostatic carcinoma is both the most common invasive cancer and the second most common cause of cancer deaths in men in the United States. Before 1991, attempts to propagate prostatic carcinoma from primary tumors for periods longer than 3 months were unsuccessful in vivo and in vitro with rare exceptions. In 1991, we reported establishment of slowly growing tumors for six of 10 human primary prostatic carcinomas approximately 2-6 months after transplantation. However, none of the tumors were larger than 5 mm or serially transplantable. PURPOSE: Our purpose in this study was to determine whether human primary prostatic carcinoma could be grown as serially transplantable xenografts. METHODS: Cells from primary prostatic carcinomas obtained from transurethral prostatic resections or total prostatectomies in 20 patients were injected subcutaneously into male nude mice on the day of surgery. Sustained-release testosterone pellets were placed subcutaneously in the mice 2-24 days before transplantation of tumors and at intervals of 10-12 weeks. Serial transplantations in subsequent generations of mice were carried out by similar methods. Chromosome analysis was performed on six tumors. RESULTS: Six of 20 primary prostatic carcinomas have grown sufficiently to permit serial transplantation into second mice; four have been documented histopathologically in the second mouse and serially transplanted into three or more successive mice. When a single primary tumor was injected into several mice by the same procedure, tumors failed to grow in some recipients but became serially transplantable in others. Growth of these tumors is slow and irregular, with frequent regressions. Short-term cultures of 10 tumors, eight of which were injected into mice in parallel, were initiated on the day of surgery; CWR31, which was successfully transplanted serially, exhibited only aberrant metaphases and showed clonal, chromosomal changes in culture. Including CWR31, three of the six tumors for which chromosomal analysis was successful contained clonal aberrations. Preliminary studies of SCID (severe combined immunodeficient) mice suggest that they are not superior to nude mice for establishment of serially transplantable prostatic carcinoma xenografts. CONCLUSIONS: A proportion of human primary prostatic carcinomas can be grown as xenografts. Four new serially transplantable xenografts (CWR21, CWR31, CWR91, and CWR22) are currently propagated in our laboratory, a resource that was not previously available. IMPLICATIONS: Our experience suggests that the most important factor in serial transplantation is the collaboration of urologists and pathologists in expediting placement of the tumor in cold saline, examination of the frozen section, and transplantation.