Widespread basal cytochrome P450 expression in extrahepatic bovine tissues and isolated cells

Kühn, Matthew J.; Putman, Ashley K.; Sordillo, Lorraine M.

doi:10.3168/jds.2019-17071

Cited by 11 publications

(8 citation statements)

References 53 publications

(75 reference statements)

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“…An additional unique and advantageous characteristic of BMEC to model the effects of vitamin E analogs is a lack of measurable CYP4F2 transcript expression (Kuhn et al, 2020). The cytochrome P450 family 4 subfamily F member 2 enzyme (CYP4F2), is thought to be the sole enzyme responsible for the breakdown of vitamin E analogs and has a preference for metabolizing non-α-tocopherol analogs of vitamin E Parker, 2002, 2007).…”

Section: Discussionmentioning

confidence: 99%

Vitamin E analogs limit in vitro oxidant damage to bovine mammary endothelial cells

Kühn

Sordillo

2021

Journal of Dairy Science

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Diseases that occur during the transition period are exacerbated when cows are unable to cope with an increased pro-oxidant load that results in oxidative stress. Dairy cattle are routinely supplemented with the vitamin E analog α-tocopherol to mitigate the severity of oxidative stress. Nonetheless, oxidative stress remains a disease predisposing condition for many dairy cattle. A better method of optimizing the antioxidant functions of vitamin E is needed. α-Tocopherol is only 1 of 8 analogs of vitamin E, all of which have varying antioxidant properties in other mammals, albeit a shorter physiological half-life compared with α-tocopherol. A primary bovine mammary endothelial cell oxidant challenge model was used to determine functions of certain vitamin E analogs. The aim of this study was to determine if other analogs, namely γ-tocopherol or γ-tocotrienol, have antioxidative functions in bovine cells and if these functions may protect cellular viability and endothelial function from oxidant damage. Physiological (10 μM) and supraphysiological (50 μM) concentrations of γ-tocopherol and γ-tocotrienol had a greater capacity to reduce accumulated reactive oxygen species derived from a nitric oxide donating pro-oxidant antagonist, when compared with α-tocopherol, after 30 min to 6 h of treatment. Further, γ-tocotrienol (10 μM) decreased cell cytotoxicity to a greater amount than other analogs at like concentrations, whereas γ-tocopherol (10 μM) reduced lipid peroxidation and apoptosis more effectively than other analogs. Last, α-tocopherol (5 and 10 μM) and γ-tocopherol (5 and 10 μM) significantly slowed pro-oxidant induced loss of endothelial cell barrier integrity over a 48-h period using an electrical cell-substrate impedance sensing system. Concerningly, γ-tocotrienol drastically reduced the endothelial barrier integrity at only 5 μM despite no apparent effect on cellular viability at like concentrations. γ-Tocotrienol, however, was also the only analog to show significant cytotoxicity and reductions in viability at supraphysiological doses (25 and 50 μM). Our results suggest that γ-tocopherol has antioxidant activities that reduces cellular damage and loss of function due to oxidant challenge as effectively as α-tocopherol. These data set the foundation for further investigation into the antioxidant properties of vitamin E analogs in other bovine cells types or whole animal models.

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Section: Discussionmentioning

confidence: 99%

Vitamin E analogs limit in vitro oxidant damage to bovine mammary endothelial cells

Kühn

Sordillo

2021

Journal of Dairy Science

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“…For this reason, experiments were additionally carried out in bovine microsomes from kidney and mammary tissues. Bovine renal tissue has the greatest CYP4F2 expression on an mRNA basis of any organ making it potentially an important contributor to systemic 20‐HETE production (Kuhn et al, 2020). Unlike the human CYP4F2 microsome preparations, whole organ bovine microsomes include most CYP450 present within a given tissue type, implying CYP4A11—a potentially considerable contributor to 20‐HETE production—is likely present and could dilute the inhibitory effects of vitamin E analogs on overall 20‐HETE concentrations (Powell et al, 1998).…”

Section: Discussionmentioning

confidence: 99%

Inhibition of 20‐hydroxyeicosatetraenoic acid biosynthesis by vitamin E analogs in human and bovine cytochrome P450 microsomes

Kühn

Sordillo

2021

Animal Physiology Nutrition

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Dairy cattle are predisposed to disease around the time of calving due to dysfunctional inflammatory responses. Oxylipids are lipid‐derived mediators that regulate all aspects of the inflammatory response, and shifts in oxylipid profiles are correlated with disease risk. For example, 20‐hydroxyeicosatetraenoic acid (HETE) is an oxylipid derived from cytochrome P450 enzymes (CYP450) found at significantly greater concentrations around calving and during clinical disease. Biosynthesis of 20‐HETE occurs almost exclusively from two specific CYP450 of which CYP450 family four sub‐family F member two (CYP4F2) is the major contributor to 20‐HETE production in humans. To further study the activities of 20‐HETE and potentially reduce its production in vivo, mitigation methods must be explored. Additional substrates of CYP4F2, such as vitamin E, are known to both increase and decrease the metabolism of other CYP4F2 substrates. This study aimed to determine whether vitamin E analogs may reduce the production of 20‐HETE through competition for CYP4F2 activity in human CYP4F2, bovine‐kidney and bovine‐mammary microsomes. Gamma‐tocopherol reduced 20‐HETE production from human and bovine‐kidney microsomes (35.3% and 27.5%, respectively) whereas γ‐tocotrienol only reduced 20‐HETE production from human microsomes (40.1%). Finally, bovine‐mammary microsomes did not produce a quantifiable amount of 20‐HETE, suggesting basal mammary CYP4F2 activity may not be a significant contributor to 20‐HETE found in milk. Together, these data show that analogs of vitamin E can reduce the production of 20‐HETE, potentially through competition with arachidonic acid for metabolism by CYP4F2, posing a potential means for limiting 20‐HETE production during clinical diseases of dairy cattle.

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“…In calves, the CYP4F2 mRNA level was the highest in the liver, followed by the testis, adrenal gland, duodenum, and jejunum, which have high α-Toc accumulation [35]. The CYP4F2 mRNA in lactating Holstein cows was significantly higher in the kidney than in the liver, lung, mammary gland, heart, skeletal muscle, spleen and uterus [38]. Furthermore, the hepatic [2,55] and mammary [2] CYP4F2 mRNA expression in transition dairy cows was investigated (described in Section 4).…”

Section: Atp-binding Cassette Transporter A1mentioning

confidence: 95%

“…In the last 10 years, several studies have shown evidence that the ovine [33,34] and bovine [35] liver may play an important role in the regulation of VE disposition because of the high expression of VE-related molecules. In addition, other peripheral tissues showed unique expression patterns for VE-related molecules and VE accumulation properties in cattle [2,[35][36][37][38]. These findings indicate that the expression of VE-related genes in the liver and non-hepatic tissues may be involved in the regulation of VE status in cows.…”

Section: Introductionmentioning

confidence: 99%

The Physiological Roles of Vitamin E and Hypovitaminosis E in the Transition Period of High-Yielding Dairy Cows

Haga

Ishizaki

Roh

2021

Animals

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Levels of alpha-tocopherol (α-Toc) decline gradually in blood throughout prepartum, reaching lowest levels (hypovitaminosis E) around calving. Despite numerous reports about the disease risk in hypovitaminosis E and the effect of α-Toc supplementation on the health of transition dairy cows, its risk and supplemental effects are controversial. Here, we present some novel data about the disease risk of hypovitaminosis E and the effects of α-Toc supplementation in transition dairy cows. These data strongly demonstrate that hypovitaminosis E is a risk factor for the occurrence of peripartum disease. Furthermore, a study on the effectiveness of using serum vitamin levels as biomarkers to predict disease in dairy cows was reported, and a rapid field test for measuring vitamin levels was developed. By contrast, evidence for how hypovitaminosis E occurred during the transition period was scarce until the 2010s. Pioneering studies conducted with humans and rodents have identified and characterised some α-Toc-related proteins, molecular players involved in α-Toc regulation followed by a study in ruminants from the 2010s. Based on recent literature, the six physiological factors: (1) the decline in α-Toc intake from the close-up period; (2) changes in the digestive and absorptive functions of α-Toc; (3) the decline in plasma high-density lipoprotein as an α-Toc carrier; (4) increasing oxidative stress and consumption of α-Toc; (5) decreasing hepatic α-Toc transfer to circulation; and (6) increasing mammary α-Toc transfer from blood to colostrum, may be involved in α-Toc deficiency during the transition period. However, the mechanisms and pathways are poorly understood, and further studies are needed to understand the physiological role of α-Toc-related molecules in cattle. Understanding the molecular mechanisms underlying hypovitaminosis E will contribute to the prevention of peripartum disease and high performance in dairy cows.

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Widespread basal cytochrome P450 expression in extrahepatic bovine tissues and isolated cells

Cited by 11 publications

References 53 publications

Vitamin E analogs limit in vitro oxidant damage to bovine mammary endothelial cells

Vitamin E analogs limit in vitro oxidant damage to bovine mammary endothelial cells

Inhibition of 20‐hydroxyeicosatetraenoic acid biosynthesis by vitamin E analogs in human and bovine cytochrome P450 microsomes

The Physiological Roles of Vitamin E and Hypovitaminosis E in the Transition Period of High-Yielding Dairy Cows

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