Cafestol: a multi-faced compound kinetics and metabolic effects of cafestol in mice

Cafestol and kahweol are two diterpenes present in unfiltered coffees such as Scandinavian-style boiled coffee, French press coffee and espresso. The health effects of cafestol and kahweol can be positive but also potentially harmful. On the one hand cafestol shows chemo-preventive properties, which might contribute to a reduction of the risk for certain cancers, especially colorectal cancer. On the other hand cafestol is known as the most potent cholesterol-raising compound present in the human diet and also causes a temporally rise in plasma ASAT and ALAT enzymes. This apparently ‘two-faced’ behavior of cafestol was the starting point of this thesis. It was demonstrated that in mice cafestol is extensively metabolized by the liver. Metabolism was found to be associated with Nrf2 activation, causing an induction of biotransformation enzymes and cellular antioxidant defense. This mechanism might explain the proposed anti-carcinogenic effects of cafestol. Furthermore, distribution studies indicated that in mice cafestol accumulates almost exclusively in liver and intestine, and suggested that cafestol undergoes enterohepatic cycling. Further studies showed that cafestol prevents the development of diet-induced obesity, its metabolic complications, and the development of hepatic steatosis in mice. Modulation of the dietary fat content was also used to study the hepatic and intestinal response to cafestol at a transcriptomic level. We showed that dietary fat content is an important determinant of the effects of cafestol. This has been evaluated for several processes already known to be influenced by cafestol, such as bile acid metabolism and Nrf2-mediated biotransformation. Furthermore it was shown that cafestol activated Nrf2-mediated biotransformation both in liver and small intestine. It is concluded that cafestol behaves as a hormetic compound. It elicits a combination of mechanisms which together determine the balance between positive and negative health outcomes. Although for some mechanisms, i.e. the induction of biotransformation enzymes and acute liver toxicity, a connection seems plausible, several questions remain regarding their interrelations. This thesis has generated new mechanistic insights in the multi-faced behavior of cafestol. More studies, including in humans, are needed to study its dose-effect relations and interactions with dietary compounds. For the time being it is advisable to keep cafestol under scrutiny. <br/

Glucose and glycogen levels in piglets that differ in birth weight and vitality

In the pig, intrauterine crowding can greatly affect postnatal characteristics, among which birth weight and locomotion. In a previous study, we discovered that piglets with a low birth weight/low vitality (L piglets) have a reduced motor performance compared to piglets with a normal birth weight/normal vitality (N piglets). A possible explanation is that L piglets lack the energy to increase their motor performance to the level of that of N piglets. Blood glucose levels (GLU) and glycogen concentrations in skeletal muscle of the front (GLYFRONT) and hind leg (GLYHIND) and the liver (GLYLIVER) at birth and during the first 96 h postpartum were compared between L and N piglets. GLU at birth was the same for both groups. After birth, GLU immediately increased in N piglets, whereas it only increased after 8 h in L piglets. L piglets showed a lower GLYHIND at birth and did not use this glycogen during the first 8 h postpartum, while N piglets showed a gradual depletion. GLYLIVER at birth was 50% lower for L piglets and was unused during the studied period while N piglets consumed half of their GLYLIVER during the first 8 h. Based on these results, it is possible that lower glycogen concentrations at birth, the delayed increase in GLU and the lower use of glycogen during the first 8 h after birth negatively affect motor performance in L piglets. However, based on this study, it is unclear whether the low mobilization of glycogen by L piglets is a consequence, rather than a cause of their lower motor performance

Does intrauterine crowding affect the force generating capacity and muscle composition of the piglet front limb?

In the pig, intrauterine competition (IUC) greatly affects postnatal traits, such as birth weight, but also locomotor capacities. In a previous study, our group discovered a lower motor performance in piglets with a low birth weight and low vitality (L piglets), compared to piglets with a normal birth weight and normal vitality (N piglets). In order to explain the force deficit causing this reduced motor performance, in a subsequent study, we investigated whether this deficit in L piglets was caused by a lower force generating capacity (FGC) of the extensors of the hind limb and/or a lower number of type II (fast-twitch) fibers in m. vastus lateralis. L piglets had a lower absolute FGC, but surprisingly, a higher relative FGC (to birth weight) in the hind limb, compared to N piglets. In addition, we found no differences in fiber composition of m. vastus lateralis. In the present study, we assessed whether this higher relative FGC is a common feature for front and hind limb locomotor muscles of L piglets. To that end, the physiological cross-sectional area of the main extensor muscles of the front limb was calculated from their volume and fiber length, in order to calculate both the absolute and the relative FGC. By immunohistochemical staining of m. triceps brachii caput longum, the percentage of type II (fast-contracting) fibers could be determined. Similar to the results of the hind limb, we found a smaller absolute FGC, but a larger relative FGC in the front limb of L piglets, compared to N piglets. In addition, m. triceps brachii caput longum did not have a different muscle fiber composition in L and N piglets. As such, we can conclude that IUC affects the locomotor muscles in the front and hind limb in a similar way and that the observed force deficit in L piglets cannot be explained by a different force generating capacity or a lower percentage of type II muscle fibers

Artificial rearing influences the morphology, permeability and redox state of the gastrointestinal tract of low and normal birth weight piglets

Background: In this study the physiological implications of artificial rearing were investigated. Low (LBW) and normal birth weight (NBW) piglets were compared as they might react differently to stressors caused by artificial rearing. In total, 42 pairs of LBW and NBW piglets from 16 litters suckled the sow until d19 of age or were artificially reared starting at d3 until d19 of age. Blood and tissue samples that were collected after euthanasia at 0, 3, 5, 8 and 19 d of age. Histology, ELISA, and Ussing chamber analysis were used to study proximal and distal small intestine histo-morphology, proliferation, apoptosis, tight junction protein expression, and permeability. Furthermore, small intestine, liver and systemic redox parameters (GSH, GSSG, GSH-Px and MDA) were investigated using HPLC. Results: LBW and NBW artificially reared piglets weighed respectively 40 and 33% more than LBW and NBW sow-reared piglets at d19 (P < 0.01). Transferring piglets to a nursery at d3 resulted in villus atrophy, increased intestinal FD-4 and HRP permeability and elevated GSSG/GSH ratio in the distal small intestine at d5 (P < 0.05). GSH concentrations in the proximal small intestine remained stable, while they decreased in the liver (P < 0.05). From d5 until d19, villus width and crypt depth increased, whereas PCNA, caspase-3, occludin and claudin-3 protein expressions were reduced. GSH, GSSG and permeability recovered in artificially reared piglets (P < 0.05). Conclusion: The results suggest that artificial rearing altered the morphology, permeability and redox state without compromising piglet performance. The observed effects were not depending on birth weight