The role of the retinoblastoma protein (Rb) in the nuclear localization of BAG-1: implications for colorectal tumour cell survival

Although the retinoblastoma susceptibility gene RB1 is inactivated in a wide variety of human cancers, the retinoblastoma protein (Rb) has been shown to be overexpressed in colon cancers, which is linked to the anti-apoptotic function of the protein. However, the mechanisms by which Rb regulates apoptosis are yet to be fully elucidated. We have established that Rb interacts with the anti-apoptotic BAG-1 (Bcl-2 associated athanogene-1) protein, and that a decrease in nuclear localization of BAG-1 is detectable when the interaction between Rb and BAG-1 is disrupted by expression of the E7 viral oncoprotein. Interestingly, although reported as deregulated in colorectal cancers, we have found that BAG-1 expression is also altered in small adenomas, where its localization was found to be predominantly nuclear. In addition, we have established that maintenance of high nuclear BAG-1 in vitro increases the resistance of adenoma-derived cells to γ-radiation-induced apoptosis. Our work suggests a novel function for Rb, involving modulation of the subcellular localization of BAG-1. We have found predominant nuclear BAG-1 localization in small adenomas, and suggest that BAG-1 may promote colorectal tumour cell survival by making colonic epithelial cells less sensitive to DNA damage.

Glycogen depletion of the intrafusal fibers in a mouse muscle spindle during prolonged swimming

This study investigated the recruitment of different types of intrafusal fibers during prolonged swimming at 60-75% of VO2max. We used 56 male adult mice and examined depletion of glycogen in soleus (Sol) and extensor digitorum longus (EDL) muscle spindles by visual inspection and a newly developed optical scanning method. More than 80% of all spindles from six mice consisted of four fibers: one type I nuclear bag (bag1) fiber, one type II nuclear bag (bag2) fiber, and two nuclear chain fibers. Glycogen content was estimated in muscle fibers from groups of six mice that had rested or swum for either 0.5, 1, 2, 4, or 8 h. The optical scanning intensity of periodic acid Schiff (PAS)-stained sections was correlated with their biochemically determined glycogen content (r = 0.93). Both methods showed fundamentally the same result: each type of intrafusal fiber has its own typical recruitment pattern during exercise. In the initial phase (0-0.5 h), glycogen depletion was largest in nuclear bag1 fibers and insignificant in the bag2 and chain fibers. With the bag1 fibers having become fatigued, nuclear bag2 fibers mainly took over during the middle phase (2-4 h). During the last phase (4-8 h), only the glycogen content of chain fibers decreased significantly (4-8 h). There were significant correlations between the recruitment pattern of bag1 and extrafusal type I fibers in both Sol and EDL, between nuclear bag2 and type IIa fibers in Sol, and between nuclear chain and type IIb fibers in EDL. This suggests that, during moderately intense exercise, glycogen depletion occurs first in the slow, then the intermediate, and, finally, the fast intrafusal fibers.

Expression of myosin heavy chain isoforms in developing human muscle spindles.

We studied serial sections of human fetal limb muscles (10-25 weeks of gestation) by light microscopic (LM) immunocytochemistry, using specific antibodies against slow-tonic, slow-twitch, fetal, embryonic, and alpha-cardiac myosin heavy chain (MHC) isoforms, neurofilament protein, laminin, and myomesin. One set of the first-generation myotubes expressed slow-tonic MHCs, and slow-twitch, fetal, and embryonic MHCs from the tenth week of gestation. These primary myotubes were identified as developing nuclear bag fibers. Second-generation myotubes in close apposition to the primary nuclear bag myotubes initially expressed only fetal and embryonic MHCs. One or more of these secondary myotubes acquired expression of slow-tonic and slow-twitch MHCs and gave rise to nuclear bag fibers. Most of the nuclear bag precursors expressed alpha-cardiac MHC. The secondary myotubes that expressed fetal and embryonic MHC but not slow-tonic, slow-twitch, or alpha-cardiac MHCs gave rise to the nuclear chain fibers. This study shows that different populations of fiber precursors, each with a unique sequence of MHC expression, gave rise to the nuclear bag and chain fibers, despite the presence of a common afferent nerve, from the early stages.