Transcriptome Characteristics and X-Chromosome Inactivation Status in Cultured Rat Pluripotent Stem Cells.

Rat pluripotent stem cells, embryonic stem cells (ESCs), and induced pluripotent stem cells (iPSCs) as mouse and human ones have a great potential for studying mammalian early development, disease modeling, and evaluation of regenerative medicine approaches. However, data on pluripotency realization and self-renewal maintenance in rat cells are still very limited, and differentiation protocols of rat ESCs (rESCs) and iPSCs to study development and obtain specific cell types for biomedical applications are poorly developed. In this study, the RNA-Seq technique was first used for detailed transcriptome characterization in rat pluripotent cells. The rESC and iPSC transcriptomes demonstrated a high similarity and were significantly different from those in differentiated cells. Additionally, we have shown that reprogramming of rat somatic cells to a pluripotent state was accompanied by X-chromosome reactivation. There were two active X chromosomes in XX rESCs and iPSCs, which is one of the key attributes of the pluripotent state. Differentiation of both rESCs and iPSCs led to X-chromosome inactivation (XCI). The dynamics of XCI in differentiating rat cells was very similar to that in mice. Two types of facultative heterochromatin described in various mammalian species were revealed on the rat inactive X chromosome. To explore XCI dynamics, we established a new monolayer differentiation protocol for rESCs and iPSCs that may be applied to study different biological processes and optimized for directed derivation of specific cell types.

Regression of Walker 256 carcinosarcoma in vasopressin-deficient Brattleboro rats is accompanied by a changed laminin pattern.

Walker 256 carcinosarcoma is a transplantable model of rat carcinoma that originally appeared spontaneously in mammary glands. The growth rate of Walker 256 carcinosarcoma in vasopressin-deficient Brattleboro rats is lower than in WAG rats and their congenic hybrids with normal vasopressin levels. Study of tumor proteins detected essential alterations. Tumor regression starting at the 14th day in Brattleboro rats was accompanied by changes in the laminin pattern. At the 21st day, the concentration of α-chains became twice as low, while ß-chains of laminin showed a sixfold increase compared to the initial equimolar correlation of bands. Congenic hybrids having one active copy of the vasopressin gene to provide a physiological level of hormone against the genetic background of Brattleboro rats show the same laminin alterations as WAG rats. They demonstrated a similar moderate increase of γ-chains and threefold growth of α- and ß-chains of laminin in tumor tissue. It is supposed that vasopressin may be involved in the regulation of relevant local stimuli to trigger renovation of the laminin composition in a course of growing Walker 256 carcinosarcoma.

Reduced Walker 256 carcinosarcoma growth in vasopressin-deficient Brattleboro rats.

The growth pattern of carcinosarcoma Walker 256 was studied in rats with different levels of vasopressin in the blood. The Brattleboro rats are unable to synthesize vasopressin in a consequence of deletion in the coding gene. Hybrids from crossbreeding of the mutant Brattleboro and normal WAG rats inherit the one intact vasopressin gene and hold nearly normal hormone level. It was found that non-strain-specific carcinosarcoma Walker 256 intensively grows in WAG rats and their offsprings from crossbreeding with Brattleboro rats, and tumor development is equally terminated in them by death. Carcinosarcoma grows less intensely in Brattleboro rats; the tumor nodes increased only within the first 2 weeks, after which, the tumor began to decrease and eventually disappeared. Infusion of exogenous vasopressin to Brattleboro rats intensifies a tumor growth in the first 2 weeks after the inoculation of Walker 256 cells; however, it does not prevent a following regression and resorption of tumors.