Cyclin D- and E-dependent kinases and the p57(KIP2) inhibitor: cooperative interactions in vivo.

This study examines in vivo the role and functional interrelationships of components regulating exit from the G1 resting phase into the DNA synthetic (S) phase of the cell cycle. Our approach made use of several key experimental attributes of the developing mouse lens, namely its strong dependence on pRb in maintenance of the postmitotic state, the down-regulation of cyclins D and E and up-regulation of the p57(KIP2) inhibitor in the postmitotic lens fiber cell compartment, and the ability to target transgene expression to this compartment. These attributes provide an ideal in vivo context in which to examine the consequences of forced cyclin expression and/or of loss of p57(KIP2) inhibitor function in a cellular compartment that permits an accurate quantitation of cellular proliferation and apoptosis rates in situ. Here, we demonstrate that, despite substantial overlap in cyclin transgene expression levels, D-type and E cyclins exhibited clear functional differences in promoting entry into S phase. In general, forced expression of the D-type cyclins was more efficient than cyclin E in driving lens fiber cells into S phase. In the case of cyclins D1 and D2, ectopic proliferation required their enhanced nuclear localization through CDK4 coexpression. High nuclear levels of cyclin E and CDK2, while not sufficient to promote efficient exit from G1, did act synergistically with ectopic cyclin D/CDK4. The functional differences between D-type and E cyclins was most evident in the p57(KIP2)-deficient lens wherein cyclin D overexpression induced a rate of proliferation equivalent to that of the pRb null lens, while overexpression of cyclin E did not increase the rate of proliferation over that induced by the loss of p57(KIP2) function. These in vivo analyses provide strong biological support for the prevailing view that the antecedent actions of cyclin D/CDK4 act cooperatively with cyclin E/CDK2 and antagonistically with p57(KIP2) to regulate the G1/S transition in a cell type highly dependent upon pRb.

Inhibition of ras-induced proliferation and cellular transformation by p16INK4.

The cyclin-dependent kinase 4 (CDK4) regulates progression through the G1 phase of the cell cycle. The activity of CDK4 is controlled by the opposing effects of the D-type cyclin, an activating subunit, and p16INK4, an inhibitory subunit. Ectopic expression of p16INK4 blocked entry into S phase of the cell cycle induced by oncogenic Ha-Ras, and this block was relieved by coexpression of a catalytically inactive CDK4 mutant. Expression of p16INK4 suppressed cellular transformation of primary rat embryo fibroblasts by oncogenic Ha-Ras and Myc, but not by Ha-Ras and E1a. Together, these observations provide direct evidence that p16INK4 can inhibit cell growth.

Tissue-specific and hormonally regulated expression of the puromycin N-acetyltransferase-encoding gene under control of the rabbit uteroglobin promoter in transgenic mice.

Transgenic mice bearing two fragments of the rabbit uteroglobin 5'-flanking region fused to the new reporter gene (pac) encoding puromycin N-acetyltransferase (PAC) showed a different pattern of expression. Transgenic lines (C0.4) harboring a 404-bp fragment (-396/+8) had a uterus-specific expression slightly inducible by estrogen, lacking detectable expression in other tissues where the uteroglobin-encoding gene is naturally expressed in rabbit. Transgenic lines (C3.2) bearing a longer fragment of 3.2-kb (-3254/+8) showed hormonally regulated expression in the uterus and the male genital tract, and detectable expression in the lung. In addition, the nonstimulated uterine expression of the transgene was higher in C0.4 lines than in C3.2 lines. It could be concluded that all sequences required for uterus-specific expression should be present within the 404-bp fragment, and that other upstream (-396) sequences are responsible for expression in the lung and male genital tract, as well as for a possible down modulation of expression in the uterus.

Immunocytochemical localization of phospholipase A2 in hamster spermatozoa.

Antibodies raised against porcine pancreatic phospholipase A2 (PLA2) react in immunoblottings with both the antigen as well as with one protein band of about 14 kDa from hamster spermatozoa extracts. Immunoblottings of proteins extracted from spermatozoon head and tail fractions also show similar results. Anti-PLA2 purified IgGs were employed for light and electron microscopic immunocytochemistry in order to detect PLA2 in hamster cauda epididymal spermatozoa. When whole mount spread spermatozoa were used under light (employing the PAP complex) or electron microscopy (using anti-rabbit gold conjugated), the acrosomal area of the gametes shows a noticeable labelling; a characteristic which is not observed in samples treated with the pre-immune serum. Immunocytochemistry undertaken in ultrathin sections from spermatozoon samples embedded in Lowicryl, demonstrates that the antigen appears preferentially distributed in the acrosome. Besides, sperm tails showed a scattered distribution of gold granules in the mitochondria of the midpiece. Results suggest that the antibody used recognizes a PLA2 which is preferentially located in the acrosome and mitochondria. On the other hand, the presence of a surface PLA2 in the plasma membrane covering the acrosome is suggested. This surface PLA2 would be probably related to the acrosome reaction phenomenon that occurs in the spermatozoon before penetrating the oocyte.