Lactoferrin from Milk: Nutraceutical and Pharmacological Properties
Abstract
:1. Introducing Lactoferrin
2. Lactoferrin’s Antimicrobial Activity
3. Nutraceutical and Immunomodulation Protective Effects
- Saraiva et al. [82] fed piglets with 3.6 g/L of bLF and showed higher IgG concentrations in serum and more IL-10, an immunomodulatory cytokine potentially limiting inflammation, was secreted by spleen cells into the culture media;
- Liu et al. [83] administering orally bLf to piglets, and found an increase of the blood NK cell populations and NK Lf receptor expression without affecting NK cell cytotoxicity, suggesting that Lf could help protect the organism of infants from infections;
- Cooper et al. [84] fed young pigs with transgenic cows’ milk containing rhLf. They showed favorable changes in systemic health in rhLf-milk fed pigs that had beneficial changes in circulating leukocyte populations with a decrease in neutrophils and increase in lymphocytes which is an indicator of decreased systemic inflammation. Moreover, favorable changes in intestinal villi architecture were also observed both in the duodenum and in the ileum of rhLf-milk fed pigs;
- Yang et al. [85] showed that the percentage of piglets with symptoms of diarrhea during the first 38 days of life was decreased, if compared with the control group, from 54% to 15% by orally administered Lf at a dose level of 155 and 285 mg/kg/day, respectively. A significant delay in the onset of diarrhea by at least 1 week in the higher Lf dose group and 4 days in the lower Lf dose group, compared with the control group of piglets, was also observed;
- Wu et al. [86] investigated the effect of enteral bLf supplementation on intestinal adaptation and barrier function in a rat model of short bowel syndrome (SBS) and they demonstrated a protective effect of Lf due to small-bowel luminal sIgA and TJ protein expression upregulation together with reduced intestinal permeability, supporting intestinal barrier integrity and providing better protection against bacterial infections;
- Arciniega-Martınez et al. [87] analyzed the effects of bLf orally administered to healthy male BALB/c mice. They found that antibodies, antibody-secreting cells, and B and T responses in both Peyer’s patches and in lamina propria were higher in bLf-treated than bLf-untreated mice, suggesting a potential application of bLf as a nutraceutical to control inflammation in the distal small intestine;
- Kawashima et al. [88] demonstrated the protective effect of Lf towards “Dry Eye Syndrome” caused by age-induced decrease in lacrimal gland secretory function. They attributed this activity to Lf anti-inflammatory properties since oral administration to aged mice of Lf alone or in combination with other antioxidants resulted in decreasing inflammatory cell infiltration in eyes. On the other hand [89] they demonstrated also that Lactoferrin administration decreases MCP-1 and TNF-α expression levels and markers for oxidative damage while increases the volume of tear secretion. Moreover, a combined dietary supplement containing fish oil, lactoferrin, zinc, vitamin C, lutein, vitamin E, γ-aminobutanoic acid, and Enterococcus faecium WB2000 improves the symptoms of dry eye syndrome with no side effects [90].
4. Anticancer Activity of Orally Administered Lactoferrin
5. Other Lactoferrin Activities
6. Lactoferrin Peptides
7. Conclusions
Acknowledgments
Conflicts of Interest
References
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Cancer Type | Mechanism of Anticancer Action | References |
---|---|---|
Breast | hLf causes arrest in the G0/G1 phase, induction of cell apoptosis and regulation of the expression of Bcl-2, Bax and activation of caspase 3. | [94] |
Cervix | hLf inhibits cervical cancer due to elevated expression of Fas and decreased the ratio of anti- to pro-apoptotic molecule Bcl-2/Bax. | [95] |
Colon | Lfcin causes arrest in the at S phase through downregulation of cyclin E1 in CaCO2 cells. | [96] |
hLF increases expression of TGF-β1, and holo-forms of LFs stimulate IL-18 secretion in CaCO2 cells. | [97] | |
Lf induces caspase-1 and IL-18. | [98] | |
bLf increases production of CD4+, CD8+, and IL-18 | [99] | |
Gastric | BLfcin induces apoptosis human gastric cancer cell line AGS. | [100] |
Head, neck, and oral | Lf induces suppression of AKT signaling via inhibition of 3-phosphoinositide-dependent protein kinase-1 expression and/or blocking of the K18-14-3-3 complex. | [101] |
bLf and [Polyphenon-B (P-B)] P-B was more effective in inhibiting hamster buccal pouch (HBP) carcinogenesis by inhibiting oxidative DNA damage, carcinogen activation, cell proliferation, invasion, and angiogenesis. | [102] | |
Lf inhibits tumor through direct cellular inhibition and immunomodulation. | [103] | |
Lf causes cell cycle arrest through downregulation of cyclin-dependent kinases and upregulation of p27 protein expression in head and neck cancer cell lines. | [104] | |
Lf derivated peptides induce apoptosis via JNK/SAPK activation in squamous cell carcinoma cell line SAS. | [105] | |
Leukemia | LfcinB6 (RRWQWR) induces citoxicity via caspase-mediated and cathepsin B-mediated mechanism in T-leukemia cells. | [106] |
Lfcin kills T-leukemia cells by triggering the mitochondrial pathway of apoptosis and through the generation of reactive oxygen species. | [107] | |
LF11-322 (PFWRIRIRR-NH2), peptide fragment derived from human lactoferricin, induces necrosis in leukemia cells (MEL and HL-60 leukemia cells). | [108] | |
Lf increases CDK6 and hyper-phosphorylated retinoblastoma protein, resulting in the induction of E2F1-dependent apoptosis in Jurkat human leukemia T lymphocytes. | [109] | |
Lung | bLf inhibits NNK-induced mouse lung tumorigenesis, through the modification of cell proliferation and/or apoptosis. | [110] |
hLf inhibits the growth of head and neck squamous cell carcinoma via direct cellular inhibition as well as systemically via immunomodulation. | [103] | |
Lf shows antiproliferative effects via hypophosphorylation of Rb on H1299 cells. | [111] | |
Lfcin inhibits VEGF expression and induces apoptosis on non-small cell lung cancer H460. | [112] | |
NCS | Lfcin inhibits tumor growth and induces apoptosis through activation of caspases in neuroblastoma cells and in vivo). | [113] |
Lf causes growth inhibition in the NMD and FN primary cell lines and in the U87MG continuous cell line (downregulation of cyclin D1 and D4). Administration of hLf with TMZ enhanced the effect of chemotherapy both in vitro and in vivo. | [114] |
Activity | Peptide | References | |
---|---|---|---|
Antibacterial | Gram positive | Lf(1–11) | [132] |
Lfcin | [133,134,135] | ||
Lfampin | [134] | ||
Gram negative | Lf(1–11) | [136] | |
Lfcin | [137,138,139] | ||
Lfampin | [140,141,142] | ||
Antiviral | Lf(1–11) | [143] | |
Lfcin | [54,144,145,146,147] | ||
Lfampin | [143] | ||
Antifungal | Lf(1–11) | [148] | |
Lfcin | [149,150] | ||
Lfampin | [151,152] | ||
Antiparasitic | Lfcin | [153] | |
Lfampin | [154] | ||
Anticancer | Lfcin | [155,156,157,158] |
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Giansanti, F.; Panella, G.; Leboffe, L.; Antonini, G. Lactoferrin from Milk: Nutraceutical and Pharmacological Properties. Pharmaceuticals 2016, 9, 61. https://doi.org/10.3390/ph9040061
Giansanti F, Panella G, Leboffe L, Antonini G. Lactoferrin from Milk: Nutraceutical and Pharmacological Properties. Pharmaceuticals. 2016; 9(4):61. https://doi.org/10.3390/ph9040061
Chicago/Turabian StyleGiansanti, Francesco, Gloria Panella, Loris Leboffe, and Giovanni Antonini. 2016. "Lactoferrin from Milk: Nutraceutical and Pharmacological Properties" Pharmaceuticals 9, no. 4: 61. https://doi.org/10.3390/ph9040061
APA StyleGiansanti, F., Panella, G., Leboffe, L., & Antonini, G. (2016). Lactoferrin from Milk: Nutraceutical and Pharmacological Properties. Pharmaceuticals, 9(4), 61. https://doi.org/10.3390/ph9040061