A synthesis of interstitial fluid regulation and lymph formation.

The interstitial fluid spaces are filled with a mat of collagen fibers, and the interstices of this mat contain a mucopolysaccharide gel ground substance. Both the collagen fibers and the gel are elastic structures that can be expanded or compacted. In the expanded state the collagen fibers are pushed far apart and pockets of free fluid develop witin the gel. In the compacted state the elastic recoil of the compressed collagen fibers and gel reticular fibrillae seems to cause suction on the fluid within the tissue spaces, thus creating a subatmospheric pressure. Measurements of interstitial fluid pressure using a perforated capsule method indicate that this is normally slightly negative (subatmospheric) in most soft tissues. However, even very slight extra filtration of fluid into the tissue spaces increases the interstitial fluid pressure toward more positive values, which in turn increases lymph flow. The increased lymph flow then decreases the interstitial fluid volume and pressure back toward normal because of two mechanism, 1) direct removal of fluid from the tissue spaces in the lymph, and 2) removal of protein from the interstitial fluid in the lymph, thus decreasing the interstitial fluid colloid osmotic pressure and allowing more effective osmosis of fluid directly from the interstitial spaces back into the capillaries.     

Sensitivity to reinforcement in successive and delayed discriminations

Pigeons' responses were recorded in successive 15-s subintervals of 60-s components of several multiple variable-interval schedules of food reinforcement. In the standard multiple schedule or successive discrimination, discriminative stimuli were present throughout each component. In the delayed discrimination or memory procedure, red or green stimuli were present in the first 15 s of components and were followed by a white stimulus for the remainder of both components. Ratios of responses in the first 15 s of the two components, where discriminative stimuli were present, were sensitive to ratios of reinforcers obtained in the two components, to the same extent in both multiple and memory procedures. In both procedures, sensitivity to reinforcement decreased systematically over component subintervals, but to a greater extent in the memory procedure where discriminative stimuli were absent. The reduction in sensitivity with time since presentation of prior discriminative stimuli in the memory procedure was therefore influenced by two main factors: delayed stimulus control by the discriminative stimuli presented earlier in the component, and a decrease in sensitivity to reinforcement with increasing time since component alternation.     

Co-regulation of senescence-associated genes by oncogenic homeobox proteins and polycomb repressive complexes

Cellular senescence is a stable cell cycle arrest that can be induced by stresses such as telomere shortening, oncogene activation or DNA damage. Senescence is a potent anticancer barrier that needs to be circumvented during tumorigenesis. The cell cycle regulator p16^INK4a is a key effector upregulated during senescence. Polycomb repressive complexes (PRCs) play a crucial role in silencing the INK4/ARF locus, which encodes for p16^INK4a, but the mechanisms by which PRCs are recruited to this locus as well as to other targets remain poorly understood. Recently we discovered the ability of the homeobox proteins HLX1 (H2.0-like homeobox 1) and HOXA9 (Homeobox A9) to bypass senescence. We showed that HLX1 and HOXA9 recruit PRCs to repress INK4a, which constitutes a key mechanism explaining their effects on senescence. Here we provide evidence for the regulation of additional senescence-associated PRC target genes by HLX1 and HOXA9. As both HLX1 and HOXA9 are oncogenes implicated in leukemogenesis, we discuss the implications that the collaboration between Homeobox proteins and PRCs has for senescence and cancer.