Paneth cells secrete antimicrobial peptides and proteins, which are "key mediators of host-microbe interactions, including homeostatic balance with colonizing microbiota and innate immune protection from enteric pathogens." Small intestinal crypts house
stem cells that serve to constantly replenish
epithelial cells that die and are lost from the
villi.
Sensing microbiota Paneth cells are stimulated to secrete
defensins when exposed to bacteria (both
Gram positive and
Gram-negative types), or such bacterial products as
lipopolysaccharide,
lipoteichoic acid,
muramyl dipeptide and
lipid A. They are also stimulated by
cholinergic signaling normally preceding the arrival of food which potentially may contain a new bacterial load. For example, research showed that in the secretory granules, murine and human Paneth cells express high levels of
TLR9. TLR9 react to
CpG-ODN and unmethylated oligonucleotides,
pathogen-associated molecular patterns (PAMPs) typical for bacterial DNA. Internalizing these PAMPs and activating TLR9 leads to
degranulation and release of antimicrobial peptides and other secretions. Surprisingly, murine Paneth cells do not express mRNA transcripts for
TLR4. These
peptides have
hydrophobic and positively charged domains that can interact with
phospholipids in
cell membranes. This structure allows defensins to insert into membranes, where they interact with one another to form pores that disrupt membrane function, leading to cell lysis. Due to the higher concentration of negatively charged
phospholipids in bacterial than vertebrate
cell membranes, defensins preferentially bind to and disrupt bacterial cells, sparing the cells they are functioning to protect. Human Paneth cells produce two α-defensins known as
human α-defensin HD-5 (DEFA5) and
HD-6 (DEFA6). HD-5 has a wide spectrum of killing activity against both Gram positive and Gram negative bacteria as well as fungi (
Listeria monocytogenes,
Escherichia coli,
Salmonella typhimurium, and C
andida albicans). Human Paneth cells also produce other AMPs including
lysozyme, secretory
phospholipase A2, and
regenerating islet-derived protein IIIA. Lysozyme is an
antimicrobial enzyme that dissolves the cell walls of many bacteria, and phospholipase A2 is an enzyme specialized in the lysis of bacterial
phospholipids .
Secretory autophagy During conventional protein secretion, proteins are transported through the
ER-Golgi complex packaged in secretory granules and released to the extracellular space. Should invasive pathogens disrupt the
Golgi apparatus, causing an impairment in the Paneth cell secretion of antimicrobial proteins, an alternative secretion pathway exists: it has been shown that
lysozyme can be rerouted through secretory
autophagy. In secretory autophagy, cargo is transported in an LC3+ vesicle and discharged at the
plasma membrane, thus bypassing the
ER-Golgi complex. Not all bacteria prompts secretory autophagy: commensal bacteria, for example, does not cause Golgi breakdown and therefore does not trigger the secretory autophagy of
lysozyme. A dysfunction in secretory autophagy is thought to be a possible contributing factor to Crohn's disease.
Phagocytic function Paneth cells maintain the health of the intestine by acting as
macrophages; it has been shown that Paneth cells clear dying cells via apoptotic cell uptake. The phagocytic function of Paneth cells was discovered using a series of experiments, one of which made use of mice that were radiated with a low dose Cesium-137 (137Cs), mimicking chemotherapy undergone by cancer patients. These findings may be significant for addressing the side effects suffered by cancer patient whose intestinal health is damaged by chemotherapy: approximately 40% of all cancer therapy patients experience gastrointestinal (GI)
mucositis during their treatment, with the number jumping to 80% in patients receiving abdominal or pelvic
irradiation.
Epithelium maintenance Paneth cells participate in the
Wnt signaling pathway and
Notch signalling pathway, which regulate proliferation of intestinal stem cells and
enterocytes necessary for epithelium cell renewal. They express the canonical Wnt ligands:
Wnt3a,
Wnt9b, and
Wnt11, which bind to
Frizzled receptors on intestinal stem cells to drive
β-catenin/
Tcf signaling. Paneth cells are also a major source of Notch ligands
DLL1 and
DLL4, binding to Notch receptors
Notch1 and
Notch2 on intestinal stem cells and
enterocyte progenitors. Recently, however, it has been discovered that the regenerative potential of intestinal epithelial cells declines over time as a result of aged Paneth cells secreting the protein
Notum, which is an extracellular inhibitor of Wnt signaling. If Notum secretion is inhibited, the regenerative potential of the intestinal epithelium could increase.
Zinc It has been established that
zinc is essential for the function of Paneth cells. A defect in the Zn transporter (ZnT)2 impairs Paneth cell function by causing uncoordinated granule secretion. Mice lacking the (ZnT)2 transporter not only exhibit impaired granule secretion, they also suffer from increased inflammatory response to lipopolysaccharide and are less capable of bactericidal activity. Normally,
zinc is stored in the secretory granules and, upon degranulation, is released in the lumen. It has been speculated that the storage of heavy metals contributes to direct antimicrobial toxicity, as Zn is released upon cholinergic PC stimulation.
Zinc deficiency is also implicated in alcohol‐induced Paneth cell α‐defensin dysfunction, which contributes to alcohol-related
steatohepatitis. Zinc can stabilize human α‐defensin 5 (HD5), which is responsible for microbiome homeostasis. In line with this, the administration of HD5 can effectively alter the microbiome (especially by increasing
Akkermansia muciniphila), and reverse the damage inflicted on the microbiome by excessive alcohol consumption. Dietary zinc deficiency on the other hand exacerbates the deleterious effect of alcohol on the bactericidal activity of Paneth cells. == Clinical significance ==